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Artificial
intelligence and global risk
Technology
is making gestures precise and brutal, and with them men.
- Theodor
Adorno
JAY SHRIRAM
GROUP OF INSTITUTIONS
Dharapuram
Road, Avinashipalayam , Tirupur-638660
Ph:0421-2313335,9047098310,www.jayshriram.com
Presented by,
GANESH.P(II-CSE)
EMAIL ID: newmoonstars@gmail.com
PHONE NO: 9585951313
Abstract
computer
systems are becoming commonplace; indeed, they are almost ubiquitous. We find
them central to the functioning of most business, governmental, military,
environmental, and health-care organizations. They are also a part of many
educational and training programs. But these computer systems, while
increasingly affecting our lives, are rigid, complex and incapable of rapid
change. To help us and our organizations cope with the unpredictable
eventualities of an ever-more volatile world, these systems need
capabilities that will enable them to adapt readily to change. They need to be
intelligent. Our national competitiveness depends increasingly on capacities
for accessing, processing, and analyzing information. The computer systems used
for such purposes must also be intelligent. Health-care providers require easy
access to information systems so they can track health-care delivery and
identify the most recent and effective medical treatments for their patients'
conditions. Crisis management teams must be able to explore alternative courses
of action and support decision making. Educators need systems that adapt to a
student's individual needs and abilities. Businesses require flexible
manufacturing and software design aids to maintain their leadership
position in information technology, and to regain it in manufacturing
Software
Risk Management is a proactive approach for minimizing the uncertainty and
potential loss associated with a project. A risk is an event or condition
that, if it occurs, has a positive or negative effect on a project’s
objectives. The three common characteristics of risk are (1) it
represents a future event, (2) it has a probability of occurring of greater
than 0%, but less than 100%, and (3) the consequence of the risk must be
unexpected or unplanned for. Future events can be categorized as
opportunity-focused (positive risk) if their consequences are favorable, or as threat-focused
(negative risk) if their consequences are unfavorable.
INTRODUCTION(Artificial intelligence)
(AI) is a field of
study based on the premise that intelligent thought can be regarded as a form
of computation—one that can be formalized and ultimately mechanized. To achieve
this, however, two major issues need to be addressed. The first issue is
knowledge representation, and the second is knowledge manipulation. Within the
intersection of these two issues lies mechanized intelligence
History
The study
of artificial intelligence has a long history, dating back to the work of
British mathematician Charles Babbage (1791–1871) who developed a
special-purpose "Difference Engine" for mechanically computing
the values of certain polynomial functions. Similar work was also done
by German mathematician Gottfried Wilhem von Leibniz (1646–1716), who
introduced the first system of formal logic and constructed machines for
automating calculation. George Boole, Ada Byron King, Countess of Lovelace,
Gottlob Frege, and Alfred Tarski have all significantly contributed to the
advancement of the field of artificial intelligence.
Knowledge representation
It has long been recognized that the language and models
used to represent reality profoundly impact one's understanding of reality
itself. When humans think about a particular system, they form a mental model
of that system and then proceed to discover truths about the system. These truths lead to the ability
to make predictions or general statements about the system. However, when a
model does not sufficiently match the actual problem, the discovery of truths
and the ability to make predictions
becomes exceedingly difficult.
A classic example of this is the pre-Copernican model in
which the Sun and planets revolved around the Earth. In such a model, it was
prohibitively difficult to predict the position of planets. However, in the
Copernican revolution this Earth-centric model was replaced with a model where
the Earth and other planets revolved around the Sun.
This new model dramatically increased the ability of
astronomers to predict celestial events.Arithmetic with Roman numerals provides a second example of how
knowledge representation can severely limit the ability to manipulate that
knowledge. Both of these examples stress the important relationship between knowledge representation and thought.
Through artificial intelligence, engineers
and computer scientists are capable of creating machines that perform dangerous
tasks in place of humans. Here, a police robot handles a live bomb.
In AI, a significant effort has gone into the development
of languages that can be used to represent knowledge appropriately. Languages
such as LISP, which is based on the lambda calculus, and Prolog, which is based on formal logic, are widely
used for knowledge representation. Variations of predicate calculus are
also common languages used by automated reasoning systems. These languages have
well-defined semantics and provide a very general framework for representing
and manipulating knowledge
Knowledge
manipulation
Many problems that humans are confronted with are not fully
understood. This partial understanding is reflected in the fact that a rigid
algorithmic solution—a routine and predetermined number of computational steps—
cannot be applied. Rather, the concept
of search is used to solve such problems. When search is used to explore the
entire solution space, it is said to be exhaustive. Exhaustive search is not
typically a successful approach to problem solving because most interesting
problems have search spaces that are simply too large to be dealt with in this
manner, even by the fastest computers. Therefore, if one hopes to find a
solution (or a reasonably good approximation of a solution) to such a problem,
one must selectively explore the problem's search space
The difficulty here is that if part of the search space is
not explored, one runs the risk that the solution one seeks will be missed.
Thus, in order to ignore a portion of a search space, some guiding knowledge or
insight must exist so that the solution will not be overlooked. Heuristics
is a major area of
AI that concerns itself with how to limit effectively the
exploration of a search space. Chess is a classic example where humans
routinely employ sophisticated heuristics in a search space. A chess player
will typically search through a small number of possible moves before selecting
a move to play. Not every possible move and countermove sequence is explored.
Only reasonable sequences are examined. A large part of the intelligence of
chess players resides in the heuristics they employ
A heuristic-based search results from the application of domain or problem-specific
knowledge to a universal search function. The success of heuristics has led to
focusing the application of general AI techniques to specific problem domains. This has led to the development of expert systems capable
of sophisticated reasoning in narrowly defined domains within fields such as
medicine, mathematics, chemistry, robotics, and aviation.
Another area that is profoundly dependent on
domain-specific knowledge is natural language processing. The ability to
understand a natural language such as English is one of the most fundamental
aspects of human intelligence, and presents one of the core challenges for the
AI community. Small children routinely
engage in natural language processing, yet it appears to be almost beyond the
reach of mechanized computation. Over the years, significant progress has been
made in the ability to parse text to discover its syntactic structure. However, much of the meaning in natural
language is context-dependent as well as culture-dependent, and capturing such
dependencies has proved highly resistant to automation.
Introduction(Global
risk)
Providing
insights to support informed decision making is the primary objective of Risk
Management. In practice, Risk Management concentrates on performing
bottom-up, detailed, continuous assessment of risk and opportunity. It
focuses on addressing the day-to-day operational risks that a program faces.
Risk Management follows a two-stage, repeatable and iterative process of
assessment (i.e., the identification, estimation and evaluation of the risks
confronting a program) and management (i.e., the planning for, monitoring of,
and controlling of the means to eliminate or reduce the likelihood or
consequences of the risks discovered). It is performed continually over
the life of a program, from initiation to retirement.
There are a variety of risks that confront the global
software industry, as illustrated in Figure 1 [McManus, 2004], which will be discussed in more detail. The
characteristics of the legal, social, economic and competitive environments
impose constraints and opportunities that help to define the nature of the
risks (and their exposure levels) for suppliers, buyers, and other stakeholders
in the software acquisition and development process.
process.
The
Concept Of Positive Risk
Positive risk refers to risk that we initiate ourselves
because we see a potential opportunity along with a potential for failure (the
negative risk associated with “loss” of the opportunity). There are
several kinds of opportunities that can be leveraged in projects if responses
to them are well-timed and prompt action is initiated [Kahkonen, 2001]. These include:
Business opportunities, e.g., product development, customer care during the
project life cycle, and
focused attention on high profit margin activities
Operational opportunities, e.g., value-added, do what is important, minimize
rework
Systemic opportunities, which typically mean long-term savings resulting from
improved safety, insurance, etc.
The Most Common/Serious Software Risks
There are numerous reasons as to why formal risk management
is difficult to implement effectively. These include the sheer number of
risk factors that have been identified in the literature. For example,
Capers Jones assessed several hundred organizations and observed over 100 risk
factors (of which 60 he discusses in detail in [Jones, 1994]). He observed, however, that few projects have more
than 15 active risk factors at any one time, but many projects have
approximately six simultaneous risk factors.
Another reason for the relatively low implementation of
formal risk management methods in practice are, according to [Kontio, 1998], the fact that risk is an
abstract or fuzzy concept for which users lack the necessary tools to more
accurately define risk for a deeper analysis. In addition, many risk
management methods may be based on risk quantification. Users may not
have the ability to provide accurate estimates for probability and
loss/opportunity projections required for a reliable risk analysis.
Table-based approaches can sometimes be too biased or too coarse for proper
risk prioritization. Risks may also have different implications for
different stakeholders (or, conversely, be perceived differently by different
stakeholders). Existing risk management methods may not provide support
for dealing with these differences. Risks may also affect a project in
more than one way.
For example, most risk management approaches focus on cost,
schedule or quality risks, but there may be combinations of risks or other
characteristics such as future required maintenance, company reputation, or
potential liability/litigation that should be considered important in
influencing the decision-making process. Finally, many current risk management
techniques may be perceived as too costly or too complex to use. Simple,
straightforward risk management techniques that require an acceptable amount of
time to produce results might be the answer.
The Risk Management Map contains five evolutionary stages
of risk management capability, defined as:
Problem
Stage: Describes circumstances when risk identification is not seen as
positive. Characterized by lack of communication which causes a
subsequent lack of coordination. Crisis management is used to address
existing problems. Risks ignored or tracked in ad-hoc fashion.
Mitigation
Stage: Details a shift from crisis management to risk management.
People become aware of risks but do not systematically confront them.
There is uncertainty as to how to communicate risks. Risks are
usually recorded, tracked and handled as discovered.
Prevention
Stage: Discusses the shift of risk management as solely a manager’s
activity to risk management as a team activity. This is a transitional
stage from avoidance of risk symptoms to identification and elimination of root
cause of risk, characterized by team, and sometimes customer,
involvement. For risk management to succeed it must occur at each level
within an organization. This stage represents a turning point from a
reactive to a more proactive approach to risk management. Risks
systematically … analyzed, planned, tracked and resolved.
Anticipation
Stage: Describes the shift from subjective to quantitative risk management,
through the use of measures to anticipate predictable risks, that is
characterized by the use of
metrics to
anticipate failures and predict future events. This stage involves the
ability to learn from, adapt to, and anticipate change, representing a
completely proactive approach to risk management. Quantified
analysis used to determine resolution cost/benefit for the project.
Opportunity Stage: This represents a positive vision of risk management
that is used to innovate and shape the future. Risks are perceived as an
opportunity to save money and do better than planned. Risk, like quality, is
everyone’s responsibility. A continuous process of identifying,
communicating and resolving risks in an open and non-threatening environment is
used. Admissions that some things are not known are acceptable and
allowances are made for their existence using a best-case, worst-case scenario.
Risk statistics are used to make organizational/process improvements.
on a detailed plan that evolves over time.
Conclusion
AI is a
young field and faces many complexities. Nonetheless, the Spring 1998 issue of AI
Magazine contained articles on the following innovative applications of AI:
This is suggestive of the broad potential of AI in the future.
1. "Case-
and Constraint-Based Project Planning for Apartment
Construction"
2. "CREWS–NS: Scheduling
Train Crews in The Netherlands"
3. "An
Intelligent System for Case Review and Risk Assessment in Social Services"
4. "CHEMREG: Using
Case-Based Reasoning to Support Health and Safety Compliance in the Chemical
Industry"
5. "MITA: An
Information-Extraction Approach to the Analysis of Free-Form Text in Life Insurance
Applications"
Bibliography
Luger, George F., and William A. Stubblefield. Artificial
Intelligence: Structures and Strategies for Complex Problem Solving. Redwood
City, CA: Benjamin/Cummings Publishing Company,
1993.
Mueller, Robert A., and Rex L. Page. Symbolic Computing
with LISP and Prolog. New York:
Wiley and Sons, 1988.
Russel, Stuart J., and Peter Norvig. Artificial
Intelligence: A Modern Approach. Englewood Cliffs, NJ: Prentice
Hall, 1994
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