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288 lines
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288 lines
14 KiB
Plaintext
Gary S. Morris
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GSM Associates
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Suite 202
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7338 Lee Highway
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Falls Church, Virginia 22046
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(703) 685-3021
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Computer Security and the Law
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I. Introduction
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You are a computer administrator for a large manufacturing
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company. In the middle of a production run, all of the
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mainframes on a crucial network grind to a halt. Production is
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delayed costing your company hundreds of thousands of dollars.
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Upon investigating, you find that a virus was released into the
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network through a specific account. When you confront the owner
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of the account, he claims he neither wrote nor released the
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virus, but admits that he has distributed his password to
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"friends" who need ready access to his data files. Is he liable
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for the loss suffered by your company? In whole, or in part? And
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if in part, for how much? These and related questions are the
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subject of computer security law. The answers may vary depending
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on the state in which the crime was committed and the judge who
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presides at the trial. Computer security law is a new field, and
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the legal establishment has yet to reach broad agreement on many
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key issues. Even the meaning of such basic terms as "data" can be
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the subject of contention.
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Advances in computer security law have been impeded by the
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reluctance on the part of lawyers and judges to grapple with the
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technical side of computer security issues [1]. This problem
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could be mitigated by involving technical computer security
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professionals in the development of computer security law and
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public policy. This article is meant to help bridge the gap
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between the technical and legal computer security communities by
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explaining key technical ideas behind computer security for
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lawyers and presenting some basic legal background for technical
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professionals.
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II. The Technological Perspective
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A. The Objectives of Computer Security
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The principal objective of computer security is to protect
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and assure the confidentiality, integrity, and availability of
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automated information systems and the data they contain. Each of
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these terms has a precise meaning which is grounded in basic
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technical ideas about the flow of information in automated
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information systems.
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B. Basic Concepts
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There is a broad, top-level consensus regarding the meaning
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of most technical computer security concepts. This is partly
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because of government involvement in proposing, coordinating, and
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publishing the definitions of basic terms [2]. The meanings of
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the terms used in government directives and regulations are
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generally made to be consistent with past usage. This is not to
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say that there is no disagreement over definitions in the
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technical community. Rather, the range of such disagreement is
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much narrower than in the legal community. For example, there is
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presently no legal consensus on exactly what constitutes a
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computer [3].
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The term used to establish the scope of computer security is
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"automated information system," often abbreviated "AIS." An AIS
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is any assembly of electronic equipment, hardware, software, and
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firmware configured to collect, create, communicate, disseminate,
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process, store, and control data or information. This includes
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numerous items beyond the central processing unit and associated
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random access memory, such as input/output devices (keyboards,
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printers, etc.)
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Every AIS is used by subjects to act upon objects. A
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subject is any active entity that causes information to flow
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among passive entities called objects. For example, subject
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could be a person typing commands which transfer information from
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a keyboard (an object) to memory (another object), or a process
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running on the central processing unit that is sending
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information from a file (an object) to a printer (another
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object).
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Confidentiality is roughly equivalent to privacy. If a
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subject circumvents confidentiality measures designed to prevent
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its access to an object, the object is said to be "compromised."
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Confidentiality is the most advanced area of computer security
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because the U.S. Department of Defense has invested heavily for
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many years to find ways to maintain the confidentiality of
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classified data in AIS [4]. This investment has produced the
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Department of Defense Trusted Computer System Evaluation
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Criteria [5], alternatively called the Orange Book after the
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color of its cover. The Orange Book is perhaps the single most
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authoritative document about protecting the confidentiality of
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data in classified AIS.
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Integrity measures are meant to protect data from
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unauthorized modification. The integrity of an object can be
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assessed by comparing its current state to its original or
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intended state. An object which has been modified by a subject
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without proper authorization is said to be "corrupted."
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Technology for ensuring integrity has lagged behind that for
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confidentiality [4]. This is because the integrity problem has
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until recently been addressed by restricting access to AIS to
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trustworthy subjects. Today, the integrity threat is no longer
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tractable exclusively through access control. The desire for
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wide connectivity through networks and the increased use of
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commercial-off-the-shelf software has limited the degree to which
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most AISs can trust its subjects. Work in integrity has been
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accelerating over the past few years, and will likely become as
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important a priority as confidentiality in the future.
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Availability means having an AIS and its associated objects
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accessible and functional when needed by its user community.
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Attacks against availability are called denial of service
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attacks. For example, a subject may release a virus which
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absorbs so much processor time that the AIS becomes overloaded.
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This area is by far the least well developed of the three
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security properties, largely for technical reasons involving the
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formal verification of AIS designs [4]. Although such
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verification is not likely to become a practical reality for many
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years, techniques such as fault tolerance and software
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reliability are used to mitigate the effects of denial of service
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attacks.
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C. Computer Security Requirements
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The three security properties of confidentiality, integrity,
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and availability are achieved by labeling the subjects and
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objects in an AIS and regulating the flow of information between
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them according to a predetermined set of rules called a security
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policy. The security policy specifies which subject labels can
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access which object labels. For example, suppose you went
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shopping and had to present your driver's license to pick up some
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badges assigned to you at the entrance, each listing a brand
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name. The policy at this store is that you can only buy brand
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names listed on one of your badges. At the check-out line, the
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cashier compares the brand name of each object you want to buy
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with the names on your badges. If there's a match, she rings it
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up. But if you choose a brand name which doesn't appear on one
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of your badges, she puts it back on the shelf. You could be
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sneaky and alter a badge, or pretend to be your neighbor who has
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more badges than you, or find a clerk who will turn a blind eye.
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No doubt the store would employ a host of measures to prevent you
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from cheating. The same situation exists on secure computer
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systems. Security measures are employed to prevent illicit
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tampering with labels, positively identify subjects, and provide
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assurance that the security measures are doing the job correctly.
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A comprehensive list of minimal requirements to secure an AIS are
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presented in the Orange Book [5].
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III. The Legal Perspective
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A. Sources of Computer Law
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The three branches of government, legislative,
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executive and judicial, produce quantities of computer law which
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are inveresly proportional to the amount of coordination needed
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for its enactment. The legislative branch, consisting of the
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Congress and fifty state legislatures, produce the smallest
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amount of law which is worded in the most general terms. For
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example, the Congress may pass a bill mandating that sensitive
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information in government computers must be protected. The
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executive branch, consisting of the Executive Office of the
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President and numerous agencies, issues regulations which
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implement the bills passed by legislatures. Thus, the Department
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of Commerce may issue regulations which establish criteria for
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determining when economic information is sensitive and describe
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how it must be protected. Finally, the judicial branch serves as
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an avenue of appeal and decides the meaning of the laws and
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regulations in specific cases. After the decisions are issued
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(and in some cases appealed) they are taken as the word of the
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law in legally similar situations.
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B. Current Views on Computer Crime
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Currently, there is no universal agreement in the legal
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community on what constitutes a computer crime. One reason is
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the rapidly changing state of computer technology. For example,
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in 1979, the U.S. Department of Justice publication [6]
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partitioned computer crime into three categories: 1) Computer
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abuse, "the broad range of international acts involving a
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computer where one or more perpetrators made or could have made
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gain and one or more victims suffered or could have suffered a
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loss;" 2) Computer crime, "illegal computer abuse [that] implies
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direct involvement of computers in committing a crime;" and
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3) Computer-related crime, "any illegal act for which a
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knowledge of computer technology is essential for successful
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prosecution." These definitions have become blurred by the vast
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proliferation of computers and computer related products over the
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last decade. For example, does altering an inventory bar code at
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a store constitute computer abuse? Should a person caught in
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such an act be prosecuted under both theft and computer abuse
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laws? Clearly, advances in computer technology should be
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mirrored by parallel changes in computer law.
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Another attempt to describe the essential features of
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computer crime has been made by Wolk and Luddy [1]. They claim
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that the majority of crimes committed against or with the use of
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a computer can be classified as follows:
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1) Sabotage: "Involves an attack against the entire
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[computer] system or against its subcomponents, and may be
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the product of foreign power involvement or penetration by a
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competitor..."
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2) Theft of services: "Using a computer at someone else's
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expense."
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3) Property crimes involving the "theft of property by and
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through the use of computers." [7]
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A good definition of computer crime should capture all acts which
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are criminal and involve computers and only those acts. Assessing
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the completeness of a definition seems problematic, but is
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tractable using technical computer security concepts. For
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example, consider the following matrix:
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Confidentiality Integrity Availability
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Sabotage X X
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Theft of Services X
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Property Crimes X X
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This shows that Wolk and Luddy's categorization is strong with
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respect to availability and weaker in the areas of
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confidentiality and integrity. Indeed, upon closer examination
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it becomes apparent that there are ways to violate
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confidentiality and integrity which do not constitute sabotage,
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theft of services, or property crimes. For example, a Trojan
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horse could append code to a word processor which sends copies of
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a user's confidential text as messages to the perpetrator's
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electronic mailbox. This isn't sabotage because no AIS
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functionality was destroyed or even altered; theft of services
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does not apply if the perpetrator is paying for his electronic
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mail account; and unless the confidential text was copyrighted,
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it is not a property crime. This analysis is significant because
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it demonstrates that examining a legal concept from a technical
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perspective can yield insights into its strengths and weaknesses
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and even suggest avenues for improvement.
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IV. Conclusion
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The development of effective computer security law and
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public policy cannot be accomplished without cooperation between
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the technical and legal communities. The inherently abstruse
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nature of computer technology and the importance of the social
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issues it generates demand the combined talents of both. At
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stake is not only a fair and just interpretation of the law as it
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pertains to computers, but more basic issues involving the
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protection of civil rights. Technological developments have
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challenged these rights in the past and have been met with laws
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and public policies which have regulated their use. For example,
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the invention of the telegraph and telephone gave rise to privacy
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laws pertaining to wire communications. We need to meet advances
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in automated information technology with legislation that
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preserves civil liberties and establishes legal boundaries for
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protecting confidentiality, integrity, and assured service. Legal
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and computer professionals have a vital role in meeting this
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challenge together.
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REFERENCES
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[1] Stuart R. Wolk and William J. Luddy Jr., "Legal Aspects of
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Computer Use," Prentice Hall, 1986, pg. 129.
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[2] National Computer Security Center, "Glossary of Computer
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Security Terms," 21 October 1988.
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[3] Thomas R. Mylott III, "Computer Law for the Computer
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Professional," Prentice Hall, 1984, pg. 131.
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[4] Gasser, Morrie, "Building a Secure Computer System," Van
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Nostrand, 1988.
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[5] Department of Defense, "Department of Defense Trusted
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Computer System Evaluation Criteria," December 1985.
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[6] United States Department of Justice, "Computer Crime,
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Criminal Justice Resource Manual," 1979.
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[7] Wolk and Luddy, pg. 117.
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