Applications edit computational complexity theory is the study of the complexity of problems that is, the difficulty of solving them. Problems can be classified by complexity class according to the time it takes for an algorithm usually a computer program to solve them as a function of the problem size. Some problems are difficult to solve, while others are easy. For example, some difficult problems need algorithms that take an exponential amount of time in terms of the size of the problem to solve. Take the travelling salesman problem, for example. It can be solved in time O(n22n)displaystyle O(n22n) (where n is the size of the network to visit the number of cities the travelling salesman must visit exactly once).
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Ho and Basu present a set of complexity measures for binary classification problems. 15 The complexity measures broadly cover: the overlaps in feature values from differing classes. The separability of the classes. Measures of geometry, topology, and density of manifolds. Instance hardness is another approach seeks to characterize the data complexity with the goal of determining how hard a data set is to classify correctly and is not biography limited to binary problems. 16 Instance hardness is a bottom-up approach that first seeks to identify instances that are likely to be misclassified (or, in other words, which instances are the most complex). The characteristics of the instances that are likely to be misclassified are then measured based on the output from a set of hardness measures. The hardness measures are based on several supervised learning techniques such as measuring the number of disagreeing neighbors or the likelihood of the assigned class label given the input features. The information provided by the complexity measures has been examined for use in meta learning to determine for which data sets filtering (or removing suspected noisy instances from the training set) is the most beneficial 17 and could be expanded to other areas. In molecular recognition edit a recent study based on molecular simulations and compliance constants describes molecular recognition as a phenomenon of organisation. 18 even for small molecules like carbohydrates, the recognition process can not be predicted or designed even assuming that each dreams individual hydrogen bond 's strength is exactly known.
Data edit In information theory, algorithmic information theory is estate concerned with the complexity of strings of data. Complex strings are harder to compress. While intuition tells us that this may depend on the codec used to compress a string (a codec could be theoretically created in any arbitrary language, including one in which the very small command "X" could cause the computer to output a very complicated string. These algorithmic measures of complexity tend to assign high values to random noise. However, those studying complex systems would not consider randomness as complexity who? Information entropy is also sometimes used in information theory as indicative of complexity. Recent work in machine learning has examined the complexity of the data as it affects the performance of supervised classification algorithms.
Chaos theory has investigated the sensitivity of systems to variations in initial conditions as one cause of complex behaviour. Mechanisms edit recent developments around artificial life, evolutionary computation and genetic algorithms have led to an increasing emphasis on complexity and complex adaptive summary systems. Simulations edit In social science, the study on the emergence of macro-properties from the micro-properties, also known as macro-micro view in sociology. The topic is commonly recognized as social complexity that is often related to the use of computer simulation in social science,. Systems edit main article: Complex system Systems theory has long been concerned with the study of complex systems (in recent times, complexity theory and complex systems have also been used as names of the field). These systems are present in the research of a variety disciplines, including biology, economics, social studies and technology. Recently, complexity has become a natural domain of interest of real world socio-cognitive systems and emerging systemics research. Complex systems tend to be high- dimensional, non-linear, and difficult to model. In specific circumstances, they may exhibit low-dimensional behaviour.
Other fields introduce less precisely defined notions of complexity: A complex adaptive system has some or all of the following attributes: 4 The number of parts (and types of parts) in the system and the number of relations between the parts is non-trivial however, there. Complexity has always been a part of our environment, and therefore many scientific fields have dealt with complex systems and phenomena. From one perspective, that which is somehow complex displaying variation without being random is most worthy of interest given the rewards found in the depths of exploration. The use of the term complex is often confused with the term complicated. In today's systems, this is the difference between myriad connecting "stovepipes" and effective "integrated" solutions. 13 This means that complex is the opposite of independent, while complicated is the opposite of simple. While this has led some fields to come up with specific definitions of complexity, there is a more recent movement to regroup observations from different fields to study complexity in itself, whether it appears in anthills, human brains, or stock markets, social systems. One such interdisciplinary group of fields is relational order theories. Behaviour edit The behavior of a complex system is often said to be due to emergence and self-organization.
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Instead of proving similar theorems, such as the basic invariance theorem, for each particular measure, it is possible to easily deduce all such results from one corresponding theorem proved in the axiomatic setting. This is a general advantage of the axiomatic approach in mathematics. The axiomatic approach to kolmogorov complexity was further developed in the book (Burgin 2005) and enjoyed applied to software metrics (Burgin and Debnath, 2003; Debnath and Burgin, 2003). In information processing, complexity is a measure of the total number of properties transmitted by an object and detected by an observer. Such a collection of properties is often referred to as a state. In physical systems, complexity is a measure of the probability of the state vector of the system. This should not be confused with entropy ; it is a distinct mathematical measure, one in which two distinct states are never conflated and considered equal, as is done for the notion of entropy in statistical mechanics.
In mathematics, krohnRhodes complexity is an important topic in the study of finite semigroups and automata. In Network theory complexity is the product of richness in the connections between components of a system, 11 and defined by a very unequal distribution of certain measures (some elements being highly connected and some very few, see complex network ). In software engineering, programming complexity is a measure of the interactions of the various elements of the software. This differs from the computational complexity described above in that it is a measure of the design of the software. In abstract sense abstract Complexity, is based on visual structures perception 12 It is complexity of binary string defined as a square of features number divided by number of elements (0's and 1's). Features comprise here all distinctive arrangements of 0's and 1's. Though the features number have to be always approximated the definition is precise and meet intuitive criterion.
This shows that tools of activity can be an important factor of complexity. Varied meanings edit In several scientific fields, "complexity" has a precise meaning: In computational complexity theory, the amounts of resources required for the execution of algorithms is studied. The most popular types of computational complexity are the time complexity of a problem equal to the number of steps that it takes to solve an instance of the problem as a function of the size of the input (usually measured in bits using the. This allows classification of computational problems by complexity class (such as p, np, etc.). An axiomatic approach to computational complexity was developed by manuel Blum.
It allows one to deduce many properties of concrete computational complexity measures, such as time complexity or space complexity, from properties of axiomatically defined measures. In algorithmic information theory, the kolmogorov complexity (also called descriptive complexity, algorithmic complexity or algorithmic entropy ) of a string is the length of the shortest binary program that outputs that string. Minimum message length is a practical application of this approach. Different kinds of Kolmogorov complexity are studied: the uniform complexity, prefix complexity, monotone complexity, time-bounded Kolmogorov complexity, and space-bounded Kolmogorov complexity. An axiomatic approach to kolmogorov complexity based on Blum axioms (Blum 1967) was introduced by mark burgin in the paper presented for publication by Andrey kolmogorov. 10 The axiomatic approach encompasses other approaches to kolmogorov complexity. It is possible to treat different kinds of Kolmogorov complexity as particular cases of axiomatically defined generalized Kolmogorov complexity.
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8 sources and factors edit There are generally rules which can be invoked to explain the origin of complexity in a given system. The source of disorganized complexity is the large number of parts in the system of interest, and the lack of correlation between elements in the system. In the case of self-organizing living systems, usefully organized complexity comes from beneficially mutated organisms being selected to survive by their environment for their differential reproductive ability or at least success over inanimate matter or less organized complex organisms. Robert Ulanowicz 's treatment of ecosystems. 9 Complexity of an object or system is a relative property. For instance, for many functions (problems such a computational complexity as time of computation is smaller when multitape turing machines are used than when Turing machines with one tape are used. Random Access Machines barbing allow one to even more decrease time complexity (Greenlaw and hoover 1998: 226 while inductive turing machines can decrease even the complexity class of a function, language or set (Burgin 2005).
Some would suggest that a system of disorganized complexity may be compared with the (relative) simplicity of planetary orbits the latter can be predicted by applying Newton's laws of motion. Of course, most real-world systems, including planetary orbits, eventually become theoretically unpredictable even using Newtonian dynamics; as discovered by modern chaos theory. 7 Organized complexity, in weaver's view, resides in nothing else than the non-random, or correlated, interaction between the parts. These correlated relationships create a differentiated structure that can, as a system, interact with other systems. The coordinated system manifests properties not carried or dictated by individual parts. The organized aspect of this form of complexity vis-a-vis to other systems than the subject system can be said to "emerge without any essay "guiding hand". The number of parts does not have to be very large for a particular system to have emergent properties. A system of organized complexity may be understood in its properties (behavior among the properties) through modeling and simulation, particularly modeling and simulation with computers. An example of organized complexity is a city neighborhood as a living mechanism, with the neighborhood people among the system's parts.
5, weaver's 1948 paper has influenced subsequent thinking about complexity. 6 The approaches that embody concepts of systems, multiple elements, multiple relational regimes, and state spaces might be summarized as implying that complexity arises from the number of distinguishable relational regimes (and their associated state spaces) in a defined system. Some definitions relate to the algorithmic basis for the expression of a complex phenomenon or model or mathematical expression, as later set out herein. Organized edit One of the problems in addressing complexity issues has been formalizing the intuitive conceptual distinction between the large number of variances in relationships extant in random collections, and the sometimes large, but smaller, number of relationships between elements in systems where constraints (related. Weaver perceived and addressed this problem, in at least a preliminary way, in drawing a distinction between "disorganized complexity" and "organized complexity". In weaver's view, disorganized complexity results from the particular system having a very large number of parts, say millions of parts, or many more. Though the interactions of the parts in a "disorganized complexity" situation can be seen as largely random, the properties of the system as a whole can be understood by using probability and statistical methods. A prime example of disorganized complexity is a gas in a container, with the gas molecules as the parts.
The study of these complex linkages at various scales is the main goal of complex systems theory. Science as shredder of 2010 takes a number of approaches to characterizing complexity; zayed. 3 reflect many of these. Neil Johnson states that "even among scientists, there is no unique definition of complexity and the scientific notion has traditionally been conveyed using particular examples." Ultimately johnson adopts the definition of "complexity science" as "the study of the phenomena which emerge from a collection. 4, contents, overview edit, definitions of complexity often depend on the concept of a confidential " system " a set of parts or elements that have relationships among them differentiated from relationships with other elements outside the relational regime. Many definitions tend to postulate or assume that complexity expresses a condition of numerous elements in a system and numerous forms of relationships among the elements. However, what one sees as complex and what one sees as simple is relative and changes with time. Warren weaver posited in 1948 two forms of complexity: disorganized complexity, and organized complexity.
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For the use in computer science, see. For other uses, see, complexity (disambiguation). Complexity characterises the behaviour of a system or model whose components interact in multiple ways and follow local rules, meaning there is no reasonable higher instruction to define the various possible interactions. 1, the stem of the word "complexity" - complex - combines the latin roots com (meaning "together and plex (meaning "woven. Contrast "complicated" where plic (meaning "folded refers to many layers. A complex system is thereby characterized by its inter-dependencies, whereas a complicated system is characterized by its layers. Complexity is generally used to characterize something with many parts where those parts interact with each other in multiple ways, culminating in a higher order of emergence greater than the sum of its parts. Just as there is no absolute daddy definition of "intelligence there is no absolute definition of "complexity the only consensus among researchers is that there is no agreement about the specific definition of complexity. However, "a characterization of what is complex is possible".