168 SAJEMS NS Vol 1 (1998) No 1 A Framework for Improving the Quality of Management Information G Ie R CiDiers and H de Jager School of Accountancy. University of Pretoria ABSTRACT Computer-created infonnation is rapidly becoming tOO great for executives and others to absorb. The quality of infonnation must therefore be enhanced to provide business managers with appropriate infonnation to make efficient decisions. This paper presents the findings of a study to clarify the main and supponive attributes of quality infonnation and the computer tools that support the production of such infonnarlon. The study presents a framework for the evaluation of the most appropriate computer equipment and applications that would lead to the improvement of infonnation quality in a particular organisation. INTRODUCTION Computing in business has developed from the mechanical processing of limited sets of data some ninety years ago to a highly sophisticated electronic tool to manage business processes from the very small too the extremely large. Organisations fmd themselves today in the sixth major generation of computers in forty-three years (Edmunds, 1987:1(9). Computers have become an integral part of success in business. In order for business to survive industry competition in the 1980's and into the 21st Century the use of computers must be part of business strategy (Griffiths 1986: 184). The expanded scope and diversity of infonnation systems and the infiltration of infonnation technology into every facet of business mean that infonnation management cannot be confined to the data processing arena - it is a corporate- wide affair. Hammer. chairman of one of the largest banks in the United States, R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATEB NR Vol 1(1998) Nr I 169 regards the corporation's three fundamental assets as people, capital, and information systems (Griffiths, 1986:185). As a resource, information is Wlique. Unlike most resources, information is not exhausted by use, rather its value can be increased by its circulation (Longley, 1982:165). TIle price-perfomlance ratio of technology has also improved many times over and is still improving. The use of information warrants more attention as many more people in the wider community outside data processing deparunents began to make use of technology (Griffiths. 1986:186). Initially the focus of computers was on the processing of data. In the 1970's the awareness of the significance and value of information became more evident. The mere processing of data shifted to the compilation of information for management. Growth in the size of organisations and an increase in the number of managers demanded a wider distribution of information within shorter periods. This caused information to expand rapidly. According to Murdock, 75% of all information available was produced in the last two decades (Murdock, 1980:4). Users are rmding it difficult to cope with the overload of information. Adams said that "computer-created information is rapidly becoming too great for executives and others to absorb" (Adams, 1977:7). The apparent overload caused by the vast volumes of information demanded in turn the development of new technology to improve the capabilities of handling this information. The growth in the computer industry has been phenomenal. Forty years ago there were virtually no computers, now the computer industry is the fourth largest industry in the world, with over three thousand firms (Awad, 1988:55). Computers offer an ever increasing variety and complexity of products, technologies and developments. The technological development emphasises the production and manipulation of ever increasing volumes of data and the presentation of acceptable information for management decision making. More recent developments include database management systems, advanced and more user-friendly programming capabilities, hypermedia, powerful processors and expert systems. A major technological trend is the convergence of computer and communication technologies. All these developments enhanced the users' ability to obtain better information for decision making. Complex alternatives such as the choice between processors, software development platforms, and networking topologies are available to management to select suitable equipment, applications and the appropriate technological environment to produce acceptable results. Because of the complex relationship between different alternatives and the impact it could have on the production of information, it is no simple task to produce the information required at the right R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 170 SAJEMS NS Vol I (1998) No 1 place, and at the right time. This wide variety of tools available to collect, manipulate and produce infonnation, presents a potential problem to management. Selection of alternatives is often made for reasons other than the production of good quality infonnation, such as price or processing power. The contribution that specific equipment and computer applications could make to improve the quality of infonnation should be considered to help management with the appropriate selection and application of computer technology. OBJECTIVES It was against this background that a study was undertaken with two main focus areas: computer tools and quality infonnation. It aimed at bringing the interrelationship of these focus areas together. The first focus area of this study was infonnation. The study of infonnation is contained in several scientific disciplines including: Infonnation Management, Psychology and other human behavioural sciences. Computer Science. and Business Science. This study approached infonnation from a very specific angle. It focused on the attributes of infonnation in a business environment. It considered the background, nature, and features of electronic infonnation in business produced by fonnal electronic infonnation systems. The second focus area was the computer equipment, applications and technology environment which produce infonnation. Computers and related technologies are very wide subjects. They are covered by Computer Science, Electronic Engineering, and Management Science. This study did not elaborate on all aspects of computer equipment. types of applications and technologies in the computer environment. It concentrated on those aspects that relate to the processing of data and the production of infonnation. Finally, the study considered the impact that the components of computer systems have on the value of infonnation. Many other factors, beside computers could affect the value of infonnation. For example, the ability of the infonnation user to deftne, interpret and react appropriately on the infonnation could greatly affect the value of infonnation. Another factor determining the value of infonnation, is the source data. The quality of the source data will have a direct impact on the quality of infonnation. Notwithstanding the impact that other factors might have on the value of infonnation. this study concentrated on the impact that computer equipment and applications have to produce quality infonnation. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATES NR Vol 1 (1998) Nr 1 171 Hypothesis Quality information is that information that can have a decisive impact on the decisions and actions of the decision maker. This study submitted that it is feasible to identify the attributes of quality information and clarified the main and supponive attributes of such information. Computer equipment and applications, collectively known as computer tools, used and managed in an organisation contribute to enhance or impair quality information. 'This study considered these tools and the role they play to suppon the production of quality information. The hypothesis was defined as follows: using the most appropriate computer equipment and applications, and managing the optimisation of the features of these tools would lead to the improvement of information quality. RESEARCH METHOD The research method of the study unfolding the hypothesis, is illustrated in Figure l. The research method included the following steps: A comprehensive literature study and synopsis of the historical development and trends of computing concluded with a sununary of the main driving forces behind computer development. The overview of the nature and characteristics of business information and the identification and compilation of the attributes of quality information isolated the main attributes and gave assurance that the attributes identified are comprehensive. The study classified the computer equipment and applications, collectively called tools, into logical groups. To ensure that a comprehensive review was done of all applicable tools that might influence the production of information, an extensive survey off computing topics was done in the literature. An assessment of the potential contribution that each group of tools identified in the step above could make to improve the attributes of quality information was then done. The characteristics of the tools and the attributes were analysed to deduce an acceptable method of assessing each tool's contribution to the production of quality information. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 172 SAJEMS NS Vol I (1998) No I Figure 1 - Overview or research method PHASE 2 , . IDENTIFY COMPUTER TOOLS ~" CONSIOf:R CONTRIBUTION OF TOOLS TOaUALITY OF INFORMA TION .-, PHASE 1 HISTOR1CAl QVERI,HEW OF COMPUTERS II "-', ~NFOAMATION / , CONS,DER NATURE: OF INFORMATION , OEFiN€ ATTFUSuTES of QUAUTY , COMPARE i .... - ... ! PHASE :3 CDMPlLE i FRAMEWORK INfORMATION , EVALUATe PERFORMANCE ~ TOOLS , To evaluate the significance of the attributes. the elements of information were refined into measurable components. The definition of these measurable components of information is described later in this study. A framework was then compiled to be used by managers to analyse information components and to identify areas of improvement to produce better quality information. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATED NR Vol 1 (1998) Nr 1 173 OVERVIEW OF COJ\.1PUTER DEVELOPMEI\'T DRIVING FORCES The literature study of the historical development and trends of computing covered computer development from the early days in the eighteenth century, to the current sixth generation of computers. The synopsis of the developments showed that a combination of key forces caused change in the computer world. Research and development opened up new possibilities. The immediate needs of society at a particular point in time, consumed the ideas of the scientists and inventors to create viable products. Research also created new opportunities to solve new problems. Factors which increased the pressures on researchers to produce better results included changes in the scales of economy, developments in areas like communication, human behavioural research, and electronics and many other disciplines. During the last forty years, the main forces behind the direction in which computers developed can be summarised as follows: • The profit motive of a major industry in the world; • increased processing power of smaller and smaller "engines"; • the widespread use of computers in all areas of life; • the connectivity of computers throughout the world; • the storage capacity of data and information for many uses. The driving forces behind the developments in the six computer generations, with the. major benefits and shortcomings of each phase, are summarised in Table 1. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . Table 1 Driving forces PHASE DRIVING FORCE Early days - natural desire to account for wealth 1800-1950 and possessions - government requirements increased size of businesses - creative forces to build calculating machines World war 2 demand for faster computations - research First - advances in processor technology Generation - awareness of scientific importance of 1951-1958 computers to universities - pUlling more power into programming systems to operate remotely Second - cost reduction in accounting Generation applications --- PRODUCTS & BENEFITS - replacing mundane tasks performed by humans - adding machines - arithmometers - mass production of data - building of powerful processors - productive programming - relation between human thinking and computer achieved - bi rth of information age - faster processors - first digital commercial computer - FORTRAN developed commencement of multiprogramming - experimentation with interactive systems and timesharing front-end processors and remote communications SHORTCOMINGS - limited stored programs - enormous computers no communication between computers - no networking - limited reliability - bulky and inOexible - used vacuum tubes for memory - required air-conditioning - handled one program at a time programming performed in machine language - little realisation of potential of software i -~ CI) (: rn 3: CI) 6i ~ j l- R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . Table I (continued) Second 1- cost reduction Generation applications in accounting I - front-end processors and remote 1 little realisation of potential of communications software need to use data communication 1959-1964 I - multi processing - transistors replacing vacuum tubes - magnetic core memory - symbolic programming languages - development of COBOL EDP managers move up organisation no software industry management lax in full in I utilisation of EDP resources upcoming data professionals processing I - ty~ical applications: payroll. accounts 1- no charge back of EDP costs receivable. accounts to users Third Generation 1965-1970 applications in all functional areas - exponential demand for computer use - appearance of software houses - growth in size of organisations and economy payable. billing - integrated circuits - improvements in speed. capacity. types of input/output, storage devices - lack of Oexibility primarily concerned record keepi ng and data processing with - management information not common high maintenance and .. .. development costs - ryplcal applications: general ledger. I - mini computers forecasting. budgeting. poor documentation inventory control - high demand for programmers en ;J> @ ttl Z ~ 9: ~ j z ... ..J IJI R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . Table 1 (continued) Fourth 1- expansion of Generation production and needs information I - significant improvement in design and 1- little inter-organisational performance communication 1970-1980 - complexity of economy and I - large scale integrated circuits enterprises increased - micro computers - further growth in number of managers and other users - Database management systems emphasis on quantitative - move towards centralised computing techniques in management - controls and standards enforced - controlled application development - restructuring of application portfolios - EDP funds tightened - surge of application software packages - emphasis on user needs - greater involvement of users - explosion in use of communication - databases and distributed computing based systems appear requirements for integrity, - user base expansion availability and reliability L--~ dependence programming on user - limited use of micro computers ~ tI) c: ~ tI) Z tI) 9: j "l: R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . Table 1 (continued Fifth Generation - user machine interface - expert systems - networking - distributed processing - client-server technology - communication - wide range user support - graphical developments - human computer interaction Sixth ,- expert systems Generation - machine translation systems - intelligent robots - cross disciplinary rescarch e.g. physiology, psychology. - vision - world wide communication VLSI architecture - parallel processing - office automation explosion of information expectation gap between users and DP departments for users and I - technology explosion - user-friendly packages - decision support systems - experimental work in expert systems - end user computing - graphics - total integration of computers - comprehensive information provider interface unde'r - expert systems not commonly used use of advanced technology limited pressure on capabilities intuitive reasoning associative recall creativity hearing smelling feeling tasting emotion - gestures ~ ~ ~ j ~ - -...) -...) R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 178 SAJEMS NS Vol 1 (1998) No J THE MAIN ATIRIBUTES OF QUALITY ~'FORI\1ATION The literature study revealed a very haphazard coverage of the attributes of quality infonnation. Some 62 adjectives, used by authors to refer to the attributes of infonnation, were identified. Most of the authors referred to 'relevancy', 'accuracy', and 'timeliness' being important attributes. Several other aqjectives relate to these. Other adjectives relate to the ability of the user to understand and work with the infonnation. Although the ability to comprehend the infonnation is closely associated with 'relevancy', there is a distinct difference between the two. 'Relevancy' has to do with the content of the infonnation. 'Comprehension' has to do with the interface between the user and the infonnation. No single concept was defined in the literature as the dominant collective term for the attributes referring to these two aspects. For the purposes of grouping all these adjectives togeLlter, "comprehensibility" is used. The four main attributes identified in the study: relevancy, accuracy, timeliness and comprehensibility, and the other adjectives associated with them are summarised in Table 2. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATEB NR Voll (1998) Nr 1 179 Table 2 Attributes of quality information Main Attribute Sub-Attributes relevancy sufficient detail I ability to manipulate not too much acceptable not too little accessible comprehensi ve available appropriate adaptable closeness to ease of access problem pertinence flexible meaningful suppon decisions fitness i authorised selective degree of integration complete accuracy limited noise credible I verifiable I reliable precise valid freedom from bias timeliness at the right time current not too late on schedule on priority i out of time comprehensibility readily understood ease of usc adequately output quality presented quantifiable clarity simplicity reproducible user friendly understandable I output R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . ISO SAJEMS NS Vol! (1998) No ! The significance of the main attributes are discussed in the following paragraphs. Relevancy Information is constantly accumulating, having reference made to it and being stored. It can be a Frankenstein monster if not controlled. Too much in store can be self-defeating, but too little causes the decision makers and problem solvers to operate without true knowledge of what they are doing. To be kept under control, information must first be analysed and categorised to ensure useful benefit to all potential users. According to Whitehouse information is knowledge; rapid and easy access to the right knowledge is intelligence (Whitehouse, 1971:2). It must be available in sufficient detail to meet the needs of the user. All information progresses from new to old and will be lost if not consciously preserved. Too much information gives retrieval problems, so information must not only consciously be preserved but must be consciously destroyed (Whitehouse, 1971 :3). The information retained must be appropriate for the users, and sufficiently close to the problem to be pertinent. Vast quantities of information are produced, more than any person can possibly need or use. A person's brain filters most of the data, and is consciously aware of it, but acts upon only a tiny fraction of it. The objective is for a management information system to be so constructed as to filter out unneeded information, and to convey only the information that supports the needs of the decision maker. The difficulty is that designers of information systems cannot know exactly what information will be relevant to an organisation. The challenge is to assess the relevancy. and to provide appropriate access to it. To be relevant. the information must apply to the action or decision to be considered. It must be close to the problem, not over-presented information but have sufficient detail and be flexible enough to provide for all the alternatives to be considered. Two users facing the same decision might use completely different information to arrive at an acceptable conclusion. For example two managers face a decision to increase production volumes. The one wi1\ primarily use production statistics and sales volume information; the other will largely base his decision on market trends, the age of the plant and equipment and make his final decision because it will please his boss. Appropriate relevancy is therefore primarily dependant on user preferences. Only when the information is available in a required form or place, can it become relevant. Non-existing information calUlOt be relevant. Information however, can be incomplete and have a low quality. The degree of fit in a R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATEB NR Vol 1 (1998) Nr 1 181 particular situation is largely dependant on the process of filtering irrelevant information, and providing easy access to that which is relevant. Because of the developments in information technology, there will be a marked increase in the quantity of rapidly accessible information and the ability to manipulate it (Longley, 1982: 165). This will not necessarily improve the relevancy of the information. Facilities must be provided to get the right information at the right time. Accuracy Any communication channel contains some background activity, which is called noise. Information can only be recognised on the channel if it transmits signals stronger than the noise. The theory of noise in a communication channel and methods to minimise it, is well established in natural sciences. It is more difficult to detennine noise in management systems. However it does exist and because it can never be eliminated, measures to improve the clarity of the messages in a management system are worthwhile to be considered. With each message the relevant question is whether the information is a close enough approximation to reality for the intended purpose. Deciding the accuracy of information depends on the nature of it. Usually accuracy is associated with quantitative information. There are two types of quantitative information: counts and measurements. Counts can be precise. A count of twelve stock. items is exact, in the sense that it is not twelve and a fraction. A measurement is never precise. Measurements are always approximations. Modem technology has made many measurements very accurate, but a margin of error always remains. Most messages in a management infonnation system are measurements, rather that counts. Inventory quantities may be obtained by counts, but the monetary amount of inventory is a measurement. Measurements of such items as the expenses of an accounting period are likely to be a fairly rough approximation. Many accounting measurements are also not precise because they are surrogates (Anthony, 1980: 127). A surrogate is a substitute measure of some phenomenon that is used because it is not feasible to measure the phenomenon directly. Profit, as defined according to certain rules, is often used as a general measure of a division's performance. Accuracy can also be associated with non quantitative information. For example, a reJXln on the attitudes of staff in the organisation. The accuracy of the infonnation cannot be measured or counted. It could however be judged by R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 182 SAJEMS NS Vol 1 (1998) No 1 comparing it with other data, for instance, general knowledge about the staff, or the result of a comparable repon. Mostly, precise measurement is not only impossible, it is also undesirable. The more precise the measuring instrument, the more it costs. There is no point in spending money to increase the precision of measurement beyond the degree of approximation that is needed to make sound decisions. For information to be accurate, it must be verifiable. To be verifiable, it should be related to other information from the same system, or to information from another system, or even to information such as verbal confirmation, prior knowledge, or 'gut feel'. Although it might not necessarily be precise, it must be credible for the needs of the user. This credibility could be supponed by the process of validation, or even beliefs or perceptions. For the information to be valid the user should be able to rely on it. Some inaccuracy of information is attributable to incorrect data producing unacceptable results. To improve the accuracy of the information, the source data must be improved. Inaccuracy could be caused by noise in the communication channel. 'This is panicularly true when the user is biased towards an expected result and therefore judge the accuracy of the information inappropriately or incorrectly. Noise in the communication channel could also result from a lack of interpretative skills, cultural background, or emotion of the user. Finally information could get lost in a channel during the process of transferring information, for example, from one person to another. There is a trade-off between precision and timeliness. Often it will take more time to produce more accurate information. Approximate information might be more useful to the decision maker than late, accurate information. Quality information must be accurate, however. The desired accuracy to form qUality information is completely dependant on the user and could vary from siruation to situation and user to user. Time6ness Timeliness simply means that the recipient can get the information when he needs it. When information is not timely, it is usually because it is late. The same piece of information might be too late for one decision maker, and just in time for the other, depending on the priorities. Information can also be received too early. Receiving it too early might result in the storage of the information until it is used, or even the loss of it when it is eventually required. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATEB NR Vol 1 (1998) Nr 1 183 An important angle of timely information is related to the time that it takes to produce the information. Preece (1990:7)quotes a study that Licklider had done in 1960. with the following results: "about 85% of my 'thinking' time was spent getting into a position to think. to make a decision. to learn something I know. Much more time went into finding or obtaining information than into digesting it. Hours went into the plotting of graphs and other hours into instruCting an assistant how to plot. When the graphs were finished, the relations were obvious at once, but the plotting had to be done in order to make them so." Although this study of Licklider is somewhat old. the problem is still very real. No information can be regarded to be timeless, a situation where there is no necessity for information to be available at a particular point in time. Every decision has a beginning and an end. The beginning commences when the need for the decision arises, the end when the decision has been made, Every piece of information used for a decision is received within a time frame, which either suits. or does not suit the time frame of the decision. The information is on schedule when it is received or available within the boundaries of the time frame of the decision. Because of the difficulty of figuring out the exact timing of when the information must be available. and the different needs of users. some information providers lean towards having the information always available on request. For instance. the accumulation of large databases of information which can be queried at any time. This trend is noticeable in document imaging, CD ROM and inter- continental information networks. These trends are indicative that the cost of information storage is less that the cost of not having the information available on time. Information that is not on time is worthless and makes no contribution to add to the relevant knowledge of the user. For information to have any quality at all, it must be on time. The degree of on time will decide the degree of quality of the information. Comprehensibility The presentation of information is vital for the actual grasping of it. It must be presented in a format that could be understood by the recipient. Recipients have preferences, some prefer graphics. some tables, and other numerical data. When information is retrieved it must be presented in a way that will enhance its meaning and ensure rapid assimilation, (Whitehouse. 1971:3). The presentation must be free from ambiguity, and should contain a clear picture for the actual purposes of the infonnation. The output must be R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 184 SAJEMS NS Vol I (1998) No I understandable. Today much is done to make computers more user friendly. This implies that as the interaction between the computer and the user improves, the presentation of information by computer is more comprehensible. Major computer development trends focus on the need for better presentation such as multimedia. graphics, high resolution screens. and Windows. The information must not only be presented. but perceived and readily understood. Without understanding, information would not be convened into knowledge by the user. Understanding is dependant on the quality of the information and t.;e abilities of the user. Despite the availability of information, or its accuracy, or even its timeliness, without comprehending the information. information will loose the benefit of all other attributes. SUMMARY OF ASSESSMENT OF COMPUTER TOOLS The study summarised the computer equipment and applications used to produce information into logical groups. These groups were illustrated as information system building blocks. Figure 2 depicts these building blocks. Figure 2 Infonnation system building blocks I I DESIGN INfORMATION SYSTEM !~ .. ------------~;~~ i i ~; INPUT TECHNOLOGY ! :OATABASES : CONTROLS , , APPllCA· :! liON l j SOFTWARI:: ; OUTPUT Butch INFOR· MATION PAD- . CESSING I COST! 1 EFFECTn,lE· NESS DEMANO The design building blocks: Input, technology, databases, controls application software and output, produce the information. These computer tools were analysed and an assessment made of the contribution that they make to the R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATES NR Vol 1 (1998) Nr I 185 production of quality information. The assessment was expressed in quantitative terms and is summarised in a comparative analysis illustrated in Figure 3. Figure 3 Comparative analysis of assessment COMPARATIVE ANAlYSIS OF ASSESSMENT AppllClltlons software 'iii Databases) Communications Processing oata t,.,sfer o 10 15 20 25 Cummulate assessment 30 OComprehensible _Timeliness Ii! Accurac:y _Relevancy 35 These assessments represent the potential of each building block to improve the attributes of quality information. The results were deduced from an analysis of the characteristics of each group of tools, the identification of the primary objective of the tool group, and the supportive role it played to enhance the quality attributes of information. The reasoning behind each assessment rating was stated in the discussion of each tool group. It is important to stress that the purpose of the study was not to make an accurate assessment of each individual computer tool. The objective was to create a framework from which the potential contribution of tool groups could be assessed. It will highlight those tools that concentrate on the achievement of specific quality attributes. The assessment would point readers in the direction to find tools that will make the most significant contribution to a specific quality attribute. If the assessment achieves this Objective, it can be regarded as a valid and successful assessment. The following general observations are made from the analysis: • All tools do not contribute equally to each attribute of quality information. • The two lowest scorers, controls and software. are both very supponive tools that do not perform primary information production roles. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 186 • • • SAJEMS NS Vol I (1998) No 1 All the tools make a good to an excellent contribution to the relevancy of infonnation. When considering quality infonnation, the model tools are by far the most significant. It is application programs that make the biggest contribution to enhance all the attributes of quality infonnation. In relation to other computer technology development, the technology that enhances the understanding and comprehension of data is relatively inunature. It is only in recent years that a major focus has been placed on this deficiency. TIle analysis illustrates this immaturity and the lack of support of the tools for comprehensibility in relation to the support for other attributes. INFORMATION COMPONENTS An infonnation component was defined in the study as the entity to be evaluated for quality attributes. An infonnation component has the following characteristics: • It is associated with a specific user, or group of users, in a specific organisation. • It has a homogeneous purpose or objective. • It demands distinguishable and homogeneous infonnation quality attributes. • It is a sub set of infonnation. • It is produced by a specific infonnation system. FRAMEWORK FOR EVALUATING THE QUALITY OF INFORMATION Following the assessment of the contribution that computer tools make to produce quality infonnation, the study compiled a framework to be used by managers to analyse infonnation and identify areas of improvement to produce better quality infonnation. There are four major generic stages to perform an evaluation of the quality of infonnation and possibilities of improvement: Decide what to evaluate, gather the infonnation, analyse the results and choose a plan of action. TIle following steps were proposed to perform the evaluation and achieve the desired results: • Select the infonnation area to be evaluated. • Decide on the infonnation components to be evaluated. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATED NR Vol 1 (1998) Nr 1 187 • Obtain responses from users of their assessment of information quality. • Conven the responses into quality attribute ratings. • Gather funher information if required. • Match anributes to the potential computer tools. • Select the tools to work on. • Design improvement program. • Carry out improvement program. Step 1 is necessary to confine the evaluation. It is impractical and virtually impossible to perform an evaluation of all information in an organisation simultaneously. Steps 2-7 will be described in funher detail in the next paragraph. Steps 8 and 9 deal with the improvement actions. The study did not deal in detail with these steps. Step 2: Decide on the information components to be evaluated and improved Using the main characteristics of an information component as identified in a previous paragraph as a guideline, the information must be reduced into information components. Usually any specific repon from an information system in the organisation will comply with the information component definition. By listing these reports and results from the information system to be evaluated this step will be completed. This listing should be done by information system and should contain the following information: • • • Step 3: Shon description of information component. User or users of the information component. Purpose or objective of information component. Obtain responses from users on their assessment of the information quality Once the information components have been identified, responses can be obtained from the users on their evaluation of the quality attributes for each information component. To simplify responses, a questionnaire can be prepared specifying, for each information component, the anribute and the appropriate scale for evaluation developed in the study. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 188 SAJEMS NS Vol 1 (1998) No 1 Step 4: Conven responses from users into quality attribute ratings for each information component When the responses have been received from the users, each questiormaire must he analysed to identify those information components and attributes in need of improvement. This can he done by putting all the returns into a small database such as Dbase. TIle record layout should contain the following fields: • Questionnaire reference. • Information component code. • Attribute code. • Rating. After all the questiormaires have been captured. the data must he soned by attribute, by rating and by information component. The result wiIJ he that all information components with incomplete information. or all information components received too early will he exposed. By analysing this information, trends can he identified. These will give rise to the type of further information to he gathered. Step 5: Gather junher information if required It is expected that further information will he required to explain the results of the analysis in step 4. It may he necessary to gather background knowledge of the information systems that produce the information component It will then he necessary to further investigate cenain replies by asking the users for the reasons hehind the replies. Step 6: Match the tools contributing 10 specific anributes The first step in homing in on the tools that can contribute the most to improve the quality of the information component, is to use Table 3 to match the attributes to the tools. The result of this comparison must he added to the database questiormaire results compiled in step 4 by adding a field for the most likely computer tool to improve the quality of the information component. If more than one tool is involved, they too should he attached to the record. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATEB NR Vol 1 (l998) Nr 1 189 Step 7: Select the tools to work on The database can then be resorted to provide an analysis by tool and by information component. The result will clearly focus the anention on those tools that can potentially improve the information components the most. The tools that can make the most significant contribution in improving the quality of the information have now been identified. All that remains to be done is to implement the improvements to the tools. This is done in steps 8 and 9. By following the steps detailed in the previous paragraphs, an organisation can find out which tools to concentrate on to provide the most benefit for improving the quality of information. This will avoid focusing on incorrect areas. For example, there is a perception that the information in an organisation is inaccurate. This would give rise to developing a new information system. However, doing an analysis according to the framework could show that the information is not understood, or that the data capturing should change. Addressing the actual problems can result in substantial savings for the organisation. CONCLUSION No major focus on the inter-relationships between information quality and computer tools was evident from the literature study. The study aimed at illustrating the importance of this relationship. Although the effect of computer tools was debated and illustrated, the study did not intend to field test the approach in the information management community. It did, however, add substantial benefit by illustrating the relationship between information quality and computer tools and by refining a framework for evaluating this quality. The study recognised the different contributions that individual tools within a building block can make to improve the quality of information. To ensure that the focus was not lost with attention to too much detail, the differential contributions of individual tools were ignored. The study focused only on groups of tools. Further studies could focus on individual tools, and highlight those tools' effect on panicular developments in technology, which could improve quality information the most. Another aspect regarding computer tools that the study steered away from, was the effect that one tool group could have on another. For instance, if processing is bad, it pulls down the effectiveness of other tool groups such as applications software. The inter-relatiOnships between tools for producing quality information, could be another important area to study further. R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . 190 SAJEMS NS Vol I (1998) No 1 The attributes of quality infonnation were deduced from the study. The literature showed the lack of commonalty among some sixty-two attributes of quality that were mentioned. Empirical studies could further enhance the understanding of exactly what users regard as the most important anributes of quality, and whether those attributes remain static. Finally, in considering methods to improve quality infonnation, the focus of the study was on computer tools. It was mentioned that the human factor. in enhancing or reducing the quality of infonnation, would be substantial. It was not the intention of the study to focus on this factor. Considering the human factor. and the interaction between computer tools and it, would offer substantial rewards to improve the ability to enhance the quality of infonnation. The hypothesis was defined as follows: "using the most appropriate computer equipment and applications, and managing the optimisation of the features of these tools would lead to the improvement of information quality. " The study considered quality infonnation and the computer tools that can improve the production of bener infonnation. After stating the objectives and research approach, it commenced with an overview of the historical development of computers. From this overview, it is apparent that the last 23 years has brought an ever-increasing focus on the development of improved computer tools to produee more efficient infonnation. The more infonnation that is being produced, the more focus there is on effective storage, manipUlation, communication, processing and presentation of infonnation. The study then examined the nature and characteristics of infonnation pointing towards the decisive impact that infonnation has on the decisions and actions of decision makers. Good infonnation, information that has quality, was then considered. The four main attributes of quality infonnation relevancy, accuracy, timeliness and comprehensibility were clarified. From the literature considered it was evident that a gap exists between infonnation produced by systems and the quality infonnation that users expect. This pointed to the need for improvement in quality infonnation. The process of producing infonnation from the initial stages of acquiring the data. through processing. communicating, storing, controlling, modelling and outputting the final infonnation was considered. Each building block of the infonnation system, and the computer equipment used, was analysed to find out their effect on the process of producing infonnation. The computer equipment was classified into groups, called computer tools. The potential contribution that these tools can make in improving the quality of infonnation was considered and rated. A method was developed to evaluate infonnation by dividing it into smaller measurable components, performing an evaluation of the quality attributes of each R ep ro du ce d by S ab in et G at ew ay u nd er li ce nc e gr an te d by th e P ub lis he r (d at ed 2 00 9) . SATES NR Voll (1998) Nr 1 191 component, and finally identifying those tools that could make the most significant comribution towards improving the quality of information components. By presenting a process of evaluation of quality information, and ways to improve it, by means of a practical framework, the hypothesis was proven. 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