Applying the Action-Research Method to Develop a Methodology to Reduce the Installation and Maintenance Times of Information Security Management Systems †
Abstract
:1. Introduction
2. State of the Art
2.1. The Action Research Method
- The researcher, which is in this case the GSyA Research Group, made up of professors at the School of Computer Sciences at the University of Castilla-La Mancha in Ciudad Real, Spain.
- The object being researched, i.e., the problem to be resolved, which is in this case improving the security management of information technologies.
- The critical reference group (CRG): those for whom the research is being carried out and who also participate in the research. This consists of the Sicaman Nuevas Tecnologías S.L. (SNT) company, its customers, and the participants in the research projects.
- The fourth participant – the beneficiary, which consists of those organisations that may benefit from the results of the work, i.e., all those small and medium-sized companies that might wish to apply advanced information security management methods to their information systems in order to improve the security of their information technology products and processes in a controlled and methodical manner. The results obtained after carting out this research will improve the efficiency of the installation and maintenance processes of information security management systems. The principal beneficiaries will therefore be all those companies that are linked to the critical reference group.
- Planning: Once the problem related to incorporation of security management systems into SMEs had been identified, we planned the development of a methodology that would allow the creation of an ISMS with the minimum number of resources, which would be adapted to the size and maturity of the company.
- Action: having defined the principal elements involved in the ISMS-creation process, we then went on to create a model and to apply it in determined case studies. The elements that would be used to construct the final ISMS were also applied in the case study.
- Observation: Once the elements had been applied and the ISMS had been created, the results obtained were evaluated. This allowed us to improve the original proposals and to eventually define a methodology that would systemise the creation and evolution of an ISMS for a company, along with a model that would permit its validation. The entire method is supported by a prototype that allows the simple generation of ISMSs and the work to be carried out with them in order to analyse their evolution over time.
- Reflection: the cyclical nature of the action research method was borne in mind, and results that were the product of successive iterations were therefore obtained. The research team has shared and contrasted these results in national and international forums related to the topics being dealt with in this research.
2.2. Security Management in SMEs
- They were developed by bearing in mind organisations that have far more resources.
- They deal with only part of the security management system, and almost none of them confront the installation of these systems from a global perspective, which obliges companies to acquire, implement, manage, and maintain various methodologies, models, and tools in order to manage security. What is more, the few applications that have attempted to tackle all the aspects of security management are expensive to acquire and require a complex management and costly maintenance, signifying that they are not appropriate for SMEs.
- Finally, it is possible to conclude that, although several standards, regulations, guidelines to good practices, security management, and risk analysis methodologies and models exist, they are not integrated into a global model that can be applied to small and medium-sized companies with guarantees of success.
3. The MARISMA Framework
- SMScG—Security Management Scheme Generation: The principal objective of this sub-process is the construction of ‘schemas’, which are the structures needed to build ISMSs, and which are created for a possible set of companies in the same category. These schemas are reusable and allow the time needed to create the ISMS to be reduced, along with its maintenance costs, thus making them suitable for the dimension of an SME [45]. The use of schemas is of particular interest in the case of SMEs since their special characteristics signify that they tend to have simple information systems that are very similar to each other. This sub-process is formed of the following activities and tasks:
- ○
- Activity A1.1—Generating master tables: T1.1.1—Establishing the roles in the schema, T1.1.2—Establishing the business sectors, T1.1.3: Establishing the maturity levels.
- ○
- Activity A1.2—Generating maturity level tables: T1.2.1—Establishing maturity rules, T1.2.2—Establishing controls.
- ○
- Activity A1.3—Generating risk analysis tables: T1.3.1—Selecting types of assets, T1.3.2—Selecting threats, T1.3.3—Selecting vulnerabilities, T1.3.4—Selecting risk criteria, T1.3.5—Establishing relationships between types of assets and vulnerabilities, T1.3.6—Establishing relationships between threats and vulnerabilities, T1.3.7—Establishing relationships between threats and controls, T1.3.8—Establishing relationships among types of assets, vulnerabilities and risk criteria.
- ○
- Activity A1.4—Generating artefact library tables: T1.4.1—Selecting rules, T1.4.2—Selecting procedures, T1.4.3—Selecting registers, T1.4.4—Selecting templates, T1.4.5—Selecting technical instructions, T1.4.6—Selecting metrics, T1.4.7—Establishing relationships between rules and artefacts, T1.4.8—Establishing relationships between rules and controls, T1.4.9—Establishing relationships between artefacts and controls, T1.4.10—Establishing relationships between procedures and artefacts.
- SMSyG—Security Management System Generation: The principal objective of this sub-process is the creation of an ISMS that is appropriate for a company by using an already-existing schema.
- ○
- Activity A2.1—Establishing the framework of the ISMS: T2.1.1—Requesting the valid interlocutor, T2.1.2—Requesting the company’s organigram, T2.1.3—Obtaining the list of information system users and their roles.
- ○
- Activity A2.2—Establishing the maturity level: T2.2.1—Gathering business information, T2.2.2—Gathering technical information from the information system, T2.2.3—Obtaining the security maturity level.
- ○
- Activity A2.3—Carrying out the risk analysis: T2.3.1—Identifying assets, T2.3.2—Generating the risk matrix and the improvement plan.
- ○
- Activity A2.4—Generation of the ISMS: T2.4.1—Generation of ISMS objects, T2.4.2—Presentation of results to interlocutor.
- SMSyM—Security Management System Maintenance: The principal objective of this sub-process is to maintain and manage the security of the company’s information system, providing information that is updated in the time of an ISMS generated.
- ○
- Activity A3.1—Obtaining and renewing safety culture certificate: T3.1.1—Taking safety culture test.
- ○
- Activity A3.2—Executing ISMS procedures: T3.2.1—Activate general procedure, T3.2.2—Activate report procedure.
- ○
- Activity A3.3—Following up the fulfilment of the ISMS: T3.3.1—Managing security scorecard, T3.3.2—Managing periodicity of procedures, T3.3.3—Managing security violations, T3.3.4—Managing safety culture certificates, T3.3.5—Realisation of periodical audits, T3.3.6—Realisation of general metrics, T3.3.7—Managing the alarm system.
4. The Research Environment
- To do so with the Sicaman Nuevas Tecnologías S.L. company’s customers in the case of ISO27001. This company was created in 1998, and one of its strategic divisions was focused on the installation of ISMSs. In 1999, the company began to implement ‘Security Management Plans’ under the BS7799 standard, and it then went on to use the UNE71502 regulation and the 17799 standard, and finally the ISO27001 standard. Tremendous faults were detected in the system from the outset, along with a low acceptance rate by customers, for whom it provided few benefits.
- To solicit help from the researchers from the Alarcos and GSyA group at the University College of Computer Science at the University of Castilla-La Mancha in order to establish a coherent and progressive methodology that would allow us to identify the faults and the reasons why the ‘Security Management Plans’ were not obtaining the desired results.
- To select a sample of 10 Spanish companies from the autonomous regions of Castilla-La Mancha and Madrid that were related to ICT, had between 10 and 50 employees (SMEs) and would be interested in installing ISMSs. The size of the companies was limited, since if they were too small (<10 employees) they would not have the minimum resources required to carry out the research, and also because they are unstable as regards changes in the market. Companies with more than 50 employees were not, meanwhile, considered because they tend to have adequate economic resources and do not, therefore, have a great need for low-cost systems.
- Initially we did not determine the duration of the research, although we estimated that it would take between five and 10 years to obtain an appropriate model. The research process eventually began in June 2005, under the UNE71502 standard, and was completed in June 2015 under the ISO27001:2013 standard.
- This research was co-financed from the outset, and continues to be so. The principal projects involved in this research are shown as follows:
- ○
- DIMENSIONS—Design and Measurement of Safe Information Systems. Code: PBC-05-012-1. Financing entity: the Autonomous Community of Castilla-La Mancha and FEDER. Participating entities: the University of Castilla-La Mancha, the University of Alicante and the University of Murcia. Duration: 1 January 2005–31 December 2007.
- ○
- MÍSTICO—Definition of a Security Model Integrated into Information and Communication Technologies. Financing entity: FEDER and the Education and Science Council of the Autonomous Community of Castilla-La Mancha. Participating entities: the University of Castilla-La Mancha, the University of Málaga and SICAMAN-NT. Duration: 1 January 2006–31 December 2008.
- ○
- SCMM-PYME—Security Maturity Model for Small and Medium-Sized Enterprises. Code: FIT-360000-2006-73. Financing entity: the Ministry of Industry, Tourism and Commerce. Participating entities: Sicaman Nuevas Tecnologías and the University of Castilla-La Mancha. Duration: 1 January 2006–31 December 2007.
- ○
- Thematic Research Network in the field of Security and Confidence for Information Systems in a Connected Society (TIN2006-26885-E). Financing entity: the Ministry of Education and Science. Participating entities: Ciudad Real City Council, European Experts in Computer Science, Sicaman Nuevas Tecnologías, University of Alicante, University of Castilla-La Mancha, Catholic University of Maule (Chile), Polytechnic University of Catalonia, University of Deusto, University of Málaga, University of Murcia, University of Rey Juan Carlos, University of Seville and University of BioBio. Duration: 1 October 2006–1 October 2007.
- ○
- SEGMENT—Security for SMEs: Integral Management and Measurement (HITO-09-138). Financing entity: The Education and Science Council of the Autonomous Community of Castilla-La Mancha. Participating entities: the University of Castilla-La Mancha and Sicaman Nuevas Tecnologías. Duration: 1 September 2009–1 September 2010.
- ○
- MARISMA—Metodology for Risk Analysis and Information Security MAnagement (HITO-2010-28). Financing entity: the Education and Science Council of the Autonomous Community of Castilla-La Mancha. Participating entities: Collaboration agreement between the University of Castilla-La Mancha and Sicaman Nuevas Tecnologías. Duration: 1 September 2010–1 September 2011.
- ○
- SIGMA_CC—Security Governance and Safe Migration of Computation Systems in the Cloud (TIN2012-36904). Financing entity: the Ministry of Economy and Competitiveness. Participating entities: the University of Castilla-La Mancha. Duration: 1 September 2012–30 September 2015.
- ○
- W2B—Commercial Innovation Project for SAAS Services (1313REDA125). Financing entity: the Autonomous Community of Castilla-La Mancha. Participating entities: Sicaman Nuevas Tecnologías. Line: innoempresa. Duration: October 2013–October 2014.
- ○
- Computational Platforms for Entertainment, Experimentation, Management and The Mitigation of Attacks against Cyber-Security (2015-PIC-019). Financing entity: the University of the Armed Forces (ESPE—Ecuador). Participating entities: the University of the Armed Forces (ESPE) and the National Network of Research and Education of Ecuador—CEDIA. Line: Research projects. Duration: 1 January 2015–31 December 2016.
- ○
- ERABAC—Risk Analysis and Valuation of Information Assets in the Cloud (1315ITA227). Financing entity: M.D. of Companies, Competitiveness and Internationalisation of the Council for Economy, Businesses and Employment of the Autonomous Community of Castilla-La Mancha. Participating entities: Sicaman Nuevas Tecnologías. Line: Business Innovation Support in Castilla-la Mancha. Duration: November 2015–November 2016.
5. Applying the Action-Research Method
5.1. Applying the Action-Research Method during the ISMS Development Phase
- Cycle I1°: Installing an ISMS using a classic process.
- ○
- Objective: To install an ISMS in the SME.
- ○
- Characteristics: An ISMS was installed and the whole process was developed to the customer’s specifications. The following were carried out: a checklist by means of controls, a maximum level risk analysis and libraries of regulations and procedures, were carried out from scratch and were totally adapted. The greatest possible number of managers was involved in the development processes.
- ○
- Principal problems detected: (i) It was impossible to organise work-related meetings without first reaching an agreement with all the managers involved; (ii) It was impossible to carry out a risk analysis owing to its detail and complexity; (iii) The users are against working with procedures on paper owing the huge amount of time needed to learn to do so; (iv) Difficulty involved in maintaining system updated and establishing corrective plans.
- ○
- Result: The customer’s general dissatisfaction with the result. The result obtained is complex and costly to maintain and is not aligned with the company’s management. The customer does not believe that it is possible to attain an acceptable ROI.
- ○
- Duration: 48 Weeks.
- Cycle I2°: Resolving aspects related to the risk analysis.
- ○
- Objective: To simplify the risk analysis.
- ○
- Characteristics: We sought to simplify the carrying out of the risk analysis by: (i) Selecting course-grained activities, i.e., activities that were as general as possible as opposed to being detailed; (ii) Simplifying the risk analysis.
- ○
- Principal problems detected: The managers of the departments were more than ready to collaborate when asked to use few words to define between 2 and 5 groups of assets that were of value to their departments. The problem of calculating and reviewing the risks was simplified to those risks related to the assets.
- ○
- Solution: The simplification of the assets of which the information system is composed.
- ○
- Result: The managers of the departments were more than ready to collaborate when asked to use few words to define between two and five groups of assets that were of value to their departments, rather than having to fill in a complex form in order to select assets and evaluations. This signified that the meeting and the asset selection processes were speeded up. Time was saved as regards calculating the risks and the risk reports, and the adaptations that have to be made when changing the value of assets.
- ○
- Associated with: Activity A1.3 (T1.3.1–T1.3.4) and A2.4 (T2.3.1).
- ○
- Duration: 44 Weeks.
- Cycle I3°: Resolution of aspects related to evaluating the level of security.
- ○
- Objective: To simplify and increase the precision of the mechanism used to evaluate the level of security.
- ○
- Characteristics: We sought to simplify and increase the precision of the activity that allows the company’s current level of security to be determined.
- ○
- Principal problems detected: When an auditor carries out an audit regarding the level to which the security controls are fulfilled, the results obtained tend to vary considerably when compared with those obtained by other auditors, thus making the evaluation of these controls very imprecise.
- ○
- Solution: The establishment of a verification list at sub-control rather than control level.
- ○
- Result: The controls were divided into more detailed questionnaires, thus reducing the margin of variation among the different auditors. Since these questionnaires are more focused, those responsible for security have less margin of error in the response and the level of evaluation can be carried out much more rapidly and efficiently.
- ○
- Associated with: Activity A1.2 (T1.2.2).
- ○
- Duration: 42 Weeks.
- Cycle I4°: Resolving aspects related to the risk analysis elements.
- ○
- Objective: To automate the risk analysis processes and to reduce time.
- ○
- Characteristics: We sought to simplify the performance of the risk analysis by predefining already existing relationships among its different elements.
- ○
- Principal problems detected: The cost of determining the risk analysis elements (types of assets, vulnerabilities, threats, and risk criteria) involved for each company is high, but in different companies with similar characteristics (e.g., the same industrial sector) more than 90% of these relationships tend to coincide.
- ○
- Solution: The creation of association matrices among each of the elements involved in the risk analysis. These matrices will be filled on the basis of the knowledge acquired during each of the installations and will associate two parts that are fundamental for the risk analysis: [Assets]–[Types of Assets, Vulnerabilities, Threats and Risk Criteria].
- ○
- Result: Huge savings as regards the consultation task needed to establish the relationships among the risk analysis elements for each of the company’s information system assets.
- ○
- Associated with: Activity A1.3 (T1.3.5, T1.3.6, T1.3.8).
- ○
- Duration: 39 Weeks.
- Cycle I5°: Resolving aspects related to the regulation and procedure libraries.
- ○
- Objective: To increase the generation of procedures and regulations.
- ○
- Characteristics: We sought to simplify the creation of the procedures and regulations that form part of the ISMS by predefining the relationships among the different elements of the ISMS.
- ○
- Principal problems detected: The cost of creating made-to-measure procedures and regulations for each installation is huge and a detailed analysis of each process is required, in addition to involving a large number of technical personnel and company staff.
- ○
- Solution: The creation of association matrices among each of the elements involved in the regulations and procedures. These matrices will be filled on the basis of the knowledge acquired during each of the installations and will be associated with three parts that are fundamental for the generation of the ISMS: [Regulations]–[Procedures]–[Elements of the Procedures: (Phases, Technical Instructions, Registers, Templates, Routes and Profiles)].
- ○
- Result: Huge savings as regards the consultation tasks needed to define the map of the company’s regulations and procedures.
- ○
- Associated with: Activity A1.4 (T1.4.1–T1.4.6).
- ○
- Duration: 31 Weeks.
- Cycle I6°: Resolving aspect related to regulation and procedure libraries.
- ○
- Objective: To reduce costs as regards the generation and maintenance of procedures and regulations.
- ○
- Characteristics: We sought to simplify the maintenance of the procedures and regulations that form part of the ISMS by establishing their relationships with the other ISMS elements.
- ○
- Principal problems detected: In order to determine whether a procedure is necessary in the ISMS, it must be associated with the controls selected for the company by means of a consultation task.
- ○
- Solution: The creation of association matrices among the regulations and procedures and the controls. These matrices will be filled on the basis of the knowledge acquired during each of the installations and will associate two parts that are fundamental for the generation of the ISMS: [Regulations]–[Controls]–[Procedures].
- ○
- Result: Huge savings as regards the consultation tasks required to establish the procedures needed for the company’s ISMS.
- ○
- Associated with: Activity A1.4 (T1.4.7–T1.4.10).
- ○
- Duration: 28 Weeks.
- Cycle I7°: Resolving aspects related to the risk analysis elements.
- ○
- Objective: To associate the risk analysis with the other elements in the ISMS.
- ○
- Characteristics: We sought to directly link the risk analysis elements with the system controls in order to unify all the elements of the ISMS.
- ○
- Principal problems detected: The results of the risk analysis are left isolated from the rest of the ISMS, signifying that a costly task must later be carried out in order to determine how to associate the risks with the controls.
- ○
- Solution: The creation of association matrices among the risk analysis and the controls. These matrices will be filled on the basis of the knowledge acquired during each of the installations and will associate the vulnerabilities with their associated controls.
- ○
- Result: Huge savings as regards the consultation task needed to establish all the relationships among the risk analysis elements and the system controls. This new matrix allows all the elements in the system to be associated with its controls, thus enabling the majority of the processes to be automated.
- ○
- Associated with: Activity A1.3 (T1.3.7).
- ○
- Duration: 26 Weeks.
- Cycle I8°: Introduction of the concept of Schema [49].
- ○
- Objective: To generate a structure that will permit knowledge reuse to be maximised (Schema).
- ○
- Characteristics: The structure denominated as Schema will be capable of containing all the lists of the elements involved in the creation of an ISMS and the relationships that exist among them.
- ○
- Principal problems detected: Having defined a set of matrices, we sought to automate and maximise its output, in addition to exploring the possibility of cloning these matrices so as to be able to carry out tests. It was also necessary to be able to incorporate any new elements that might appear during the research in an organised manner and to be able to distinguish these matrices on the basis of a series of characteristics (e.g., business sectors).
- ○
- Solution: The creation of a structure that is capable of containing all the elements involved in the ISMS generation and maintenance process, which will additionally be able to involve new elements in its structure in a simple manner and to allow an unlimited number of configurations.
- ○
- Result: Huge savings as regards the consultation task and the organisation needed to create the ISMS, since all the knowledge acquired in different installations is stored in the ‘schema’ structure.
- ○
- Associated with: the SMSG sub-process.
- ○
- Duration: 18 Weeks.
- Cycle I9°: Introduction of the concept of Maturity Level.
- ○
- Objective: To establish evaluation processes and partial certification.
- ○
- Characteristics: The introduction of partial certification and the concept of Maturity Level as an evaluation mechanism.
- ○
- Principal problems detected: Many customers still considered the process to be very complex, and control points were therefore immediately required in order to deal with the projects with the closest deadlines.
- ○
- Solution: The introduction of the possibility of establishing a certification and partial evaluation process by means of maturity levels. Tests were carried out with one level (cancel this concept), three levels, and five levels during the research. The results showed that SMEs tend to be more comfortable with a three-level system, although the process is carried out in such a way that variations are possible.
- ○
- Result: Although involving a new management element implied an increase in costs, we consider that this cost is mitigated in the medium term by the improvements that it provides. The principal advantage is that it helps ensure that the installation and maintenance process will have a higher percentage of success.
- ○
- Associated with: Activity A1.1 (T1.1.3).
- ○
- Duration: 20 Weeks.
- Cycle I10°: Broadening the concept of Maturity Level.
- ○
- Objective: To determine the maximum maturity level for a company by establishing a set of ‘maturity rules’.
- ○
- Characteristics: Determining the maximum maturity level that the company must attain on the basis of its current business structure.
- ○
- Principal problems detected: Many customers attempt to comply with controls that exceed their current business capacity and overdimension the security management systems, which leads to an increase in risks in the medium term.
- ○
- Solution: The selection of a series of business characteristics that allows the determination of maximum maturity levels that it would be advisable for the company to attain, bearing in mind its current properties, with the objective of avoiding overdimensioning or assigning resources to controls of less priority. This was done by carrying out a study of the companies’ characteristics and determining certain factors that influence their capabilities, and then establishing a simple algorithm that determines the most desirable level of security management at a particular moment.
- ○
- Result: Although involving a new management element implied an increase in costs, we consider that this cost is mitigated in the medium term by the improvements that it provides. The principal advantage is that it helps ensure that the installation and maintenance process will have a higher percentage of success.
- ○
- Associated with: Activity A1.2 (T1.2.1).
- ○
- Duration: 21 Weeks.
- Cycle I11°: Broadening the concept of Maturity Level.
- ○
- Objective: To introduce the concept of Maturity Level into the Schema structure.
- ○
- Characteristics: To introduce the concept of Maturity Level into the Schema structure in order to propagate its properties and advantages to the other elements in the schema.
- ○
- Principal problems detected: The concept of Maturity Level contributes new characteristics to the ISMS, but a costly management task is required to apply it to the different objects.
- ○
- Solution: The association of the levels of the sub-controls in the schema, such that they are propagated to all the elements in the ISMS, thus allowing the customer to know the maturity level of the security management at all times, and what must be done to attain the following level.
- ○
- Result: A reduction in the costs associated with the introduction of the ‘maturity level’ element.
- ○
- Associated with: Activity A1.2 (T1.2.2).
- ○
- Duration: 17 Weeks.
- Cycle I12°: Establishing the concept of Maturity Level.
- ○
- Objective: To introduce the concept of Current Maturity Level (the level that company currently has, based on the formulas proposed in the methodology) and the Desirable Maturity Level (the level that the company should attain bearing in mind its current safety culture) into the system installation and maintenance process.
- ○
- Characteristics: The ability to determine the Current Maturity Level and the Desirable Maturity Level of the company’s security management during the installation process, along with the overdimensioning of the security controls.
- ○
- Principal problems detected: The customer wishes to have a simple means to know the current situation, the point that must be reached, and the recovery of resources in order to reach that point with guarantees.
- ○
- Solution: The information needed to apply the algorithm that determines the company’s current situation was obtained by: choosing the most appropriate schema for that company and using questionnaires in order to determine the current security level and the desirable security level.
- ○
- Result: Although no savings were made as regards costs, the customer’s knowledge and confidence in the process increased.
- ○
- Associated with: Activity A2.2 (T2.2.1–T2.2.3).
- ○
- Duration: 17 Weeks.
- Cycle I13°: Automating the risk analysis.
- ○
- Objective: To automate the generation of the risk analysis in order to optimise the costs of this process.
- ○
- Characteristics: The creation of algorithms that employ all the information obtained to generate a basic low-cost risk analysis.
- ○
- Principal problems detected: The customer wished to be involved in the risk analysis process as little as possible, and wished above all else to minimise costs.
- ○
- Solution: The information needed to apply an algorithm that would generate (i) a matrix of all the risks to which the assets were subjected and (ii) a simplified improvement plan to present to the customer, thus enabling him to understand how and why the improvement had been made, was obtained by choosing (i) the most appropriate schema for the company and (ii) a basic set of course-grained assets.
- ○
- Result: Savings were made as regards costs, and a complete risk analysis that would be easy to maintain and regenerate was obtained.
- ○
- Associated with: Activity A2.3 (T2.3.2).
- ○
- Duration: 15 Weeks.
- Cycle I14°: Automating the elements of the ISMS.
- ○
- Objective: To automate the selection and generation of the elements of the ISMS in order to optimise the costs of this process.
- ○
- Characteristics: The creation of algorithms that utilise all the information obtained to select the most appropriate elements for the company’s ISMS.
- ○
- Principal problems detected: The process used to select the elements of which the ISMS should be composed required a consultant to carry out an analysis of all the information obtained until that time, which was a costly and complex process.
- ○
- Solution: The information needed to apply an algorithm that automatically selects and installs the elements of which the ISMS is formed was obtained by choosing the most appropriate schema for the company and by using information obtained from the customer.
- ○
- Result: Savings were made as regards costs, and an ISMS that was simple to maintain and regenerate was installed.
- ○
- Associated with: Activity A2.4 (T2.4.1).
- ○
- Duration: 12 Weeks.
5.2. Conclusions Reached after Applying the Action-Research Method during the ISMS Development Phase
5.3. Applying the Action Research Method during the ISMS Maintenance Phase
- Cycle M1°: Initial process.
- ○
- Objective: The users begin utilising the security management system.
- ○
- Characteristics: (i) The procedures generated by the system are used on paper; (ii) There is no support tool; (iii) The level of security management is known every 2–3 years when a periodical audit is carried out.
- ○
- Principal problems detected: (i) the users consider that it is very complicated to know the functioning of the procedures; (ii) the person responsible for security is overwhelmed by the cost of maintaining the system; (iii) not knowing which part of the system needs more resources leads the system to undergo progressive degradation.
- ○
- Solution: Generalised changes as regards the way work is carried out.
- ○
- Result: The current way of working leads to a medium-term failure rate in over 80% of the cases in which the system has been installed.
- Cycle M2°: Improvements oriented towards controlling the security level.
- ○
- Objective: To discover the security level of the controls at all times.
- ○
- Characteristics: The person responsible for security must, at all times, know which controls are degrading, with the objective of being able to balance the resources that are available.
- ○
- Principal problems detected: Not knowing the level of security management so as to be able to control it in the short term signifies that it is not possible to take the measures that are necessary to prevent the system from functioning incorrectly.
- ○
- Solution: The introduction of the concept of the scorecard.
- ○
- Result: The introduction of the concept of the scorecard led to a reduction in the failure rate of between 75% and 80%.
- ○
- Associated with: Activity A3.3.
- Cycle M3°: Improvements oriented towards controlling the security level.
- ○
- Objective: The use of a tool and metrics to automate the maintenance of the security scorecard.
- ○
- Characteristics: The person responsible for security must, at all times, know which controls are degrading with the objective of being able to balance the resources that are available, but it must not take much time to acquire this knowledge.
- ○
- Principal problems detected: it is necessary to introduce the concept of the scorecard, but as this cannot depend on the continual audits carried out by the person responsible for security we must rather incorporate automation processes.
- ○
- Solution: The introduction of a tool with metrics that will enable the security scorecard maintenance process to be automated.
- ○
- Result: The introduction of the tool and the metrics led to a reduction in the failure rate of between 60% and 70%.
- ○
- Associated with: Activity A3.3 (T3.3.1–T3.3.7).
- Cycle M4°: Improvements oriented towards procedure management.
- ○
- Objective: To automate the use of the procedures by means of a tool.
- ○
- Characteristics: The person responsible for security and the users must, at all times, know the functioning of all the procedures, although the majority of those procedures do not directly affect them.
- ○
- Principal problems detected: The complexity of having to know all the procedures and comply with them manually leads to a large number of non-compliances and errors in the system, in addition to the users being generally against this means of working.
- ○
- Solution: Extending the tool to contain the system procedures such that the users only have to interact with the part that directly affects them, thus signifying that they now only need to know the name and objective of the procedure.
- ○
- Result: The automation of the procedures led to a reduction in the failure rate of between 30% and 40%, and greatly simplified work with the system.
- ○
- Associated with: Activity A3.2 (T3.2.1–T3.2.2).
- Cycle M5°: Introducing the concept of the safety culture [50].
- ○
- Objective: To introduce the system users to the concept of the safety culture.
- ○
- Characteristics: The users tend to violate the regulations because they do not know them.
- ○
- Principal problems detected: It was detected that the majority of the errors and failures in the system were the result of mistakes and a lack of knowledge of the regulations related to the system.
- ○
- Solution: The users must be obliged to attain at least a minimum knowledge of the system in order to work with it, and should therefore be obliged to obtain a simple safety culture certificate that will guarantee this minimum knowledge.
- ○
- Result: The introduction of the concept of the safety culture led to a reduction in the failure rate of between 20% and 30%, which is considered adequate as regards installing the ISMS with guarantees.
- ○
- Associated with: Activity A3.1 (T3.1.1).
5.4. Conclusions Reached after Applying the Action Research Method during the ISMS Maintenance Phase
5.5. Strengths and Weaknesses of the Research
- Strengths: We consider that the principal strength of this research has been its practical application in real cases, which has allowed us to carry out a genuine technological transfer of a problem that exists in the company, which has been resolved by applying a scientific method such as Action-Research. We can also conclude that the utility of the Action-Research method has been demonstrated within the field of Information Security Management Systems.
- Weaknesses: various events occurred during the research (a 10-year cycle) that obliged us to modify/adapt the research. Of these we should highlight the economic crisis of 2007, which led two companies to discontinue the use of their ISMS for financial motives, and these had to be replaced with two other similar companies. We can conclude that the principal weakness as regards applying the Action Research method to ISMSs is its slowness, since it is necessary to carry out cycles of various years in order to reach relevant conclusions.
- Contribution to existing literature: During the period of research we have shared the results obtained with the scientific community. This amounts to almost 100 contributions (two books, three book chapters, more than 20 papers in journals, more than 40 publications at congresses, and more than 25 professional presentations). These have served to enrich the methodology upon obtaining the validation of the lessons learnt after applying the Action-Research method and providing the customers with improvements. The publications were oriented towards not only the scientific but also the professional community. This research therefore supposes an important contribution towards the existing literature on Information Security Management Systems.
6. Conclusions
- A suitable method with which to manage security and its level of maturity in SMEs’ information systems.
- A security maturity and management model based on the methodology developed and denominated as the base schema, which is appropriate for the resources of SMEs. The result was accepted by the critical reference group.
- Benefits for the participants: scientific benefits for the researcher and practical benefits for the beneficiaries.
- The knowledge obtained can be applied immediately.
Acknowledgments
Author Contributions
Conflicts of Interest
References
- Von Solms, R. Information Security Management: Processes and Metrics. Ph.D. Thesis, Degree-Granting University, Johannesburg, South Africa, 2014. [Google Scholar]
- Santos-Olmo, A.; Sánchez, L.E.; Rosado, D.G.; Fernández-Medina, E.; Piattini, M. Aplicación del método de Investigación-Acción para desarrollar una Metodología Ágil de Gestión de Seguridad de la Información. In Proceedings of the VIII Congreso Iberoamericano de Seguridad Informática (CIBSI15), Quito, Ecuador, 10–12 November 2015; pp. 14–27. (In Spanish)
- Candiwan, C. Analysis of ISO27001 Implementation for Enterprises and SMEs in Indonesia. In Proceedings of the International Conference on Cyber-Crime Investigation and Cyber Security (ICCICS2014), Kuala Lumpur, Malaysia, 17–19 November 2014; pp. 50–58.
- Whitman, M.; Mattord, H. Principles of Information Security; Cengage Learning: Boston, MA, USA, 2012. [Google Scholar]
- Lampson, B.W. Computer Security in the Real World. IEEE Comput. Soc. 2004, 37, 37–46. [Google Scholar] [CrossRef]
- Whitman, M.; Mattord, H. Management of Information Security; Cengage Learning: Boston, MA, USA, 2013. [Google Scholar]
- Lampson, B. Protection. ACM Oper. Syst. Rev. 1974, 8, 18–24. [Google Scholar] [CrossRef]
- Saltzer, J.H. Protection and the Control of Information Sharing in Multics. Commun. ACM 1974, 17, 388–402. [Google Scholar] [CrossRef]
- Denning, E.D. A lattice model of secure information flow. Commun. ACM 1976, 19, 236–243. [Google Scholar] [CrossRef]
- Ellison, C. SPKI Certificate Theory. Available online: http://www.ietf.org/rfc/rfc2692.txt (accessed on 11 July 2016).
- Vivas, T.; Zambrano, A.; Huerta, M. Mechanisms of security based on digital certificates applied in a telemedicine network. In Engineering in Medicine and Biology Society, 2008. EMBS 2008, Proceedings of the 30th Annual International Conference of the IEEE, Vancouver, BC, Canada, 20–24 August 2008.
- Sandhu, R. Role-Based Access Control Models. IEEE Comput. 1996, 29, 38–47. [Google Scholar] [CrossRef]
- Eloff, J.; Eloff, M. Information Security Management—A New Paradigm. In Proceedings of the 2003 Annual Research Conference of the South African Institute of Computer Scientists and Information Technologists on Enablement through Technology (SAICSIT '03), Fourways, South Africa, 17–19 September 2003; pp. 130–136.
- Disterer, G. Iso/iec 27000, 27001 and 27002 for information security management. J. Inf. Secur. 2013, 4, 92–100. [Google Scholar] [CrossRef]
- Beckers, K.; Faßbender, S.; Heisel, M.; Küster, J.C.; Schmidt, H. Supporting the Development and Documentation of ISO 27001 Information Security Management Systems through Security Requirements Engineering Approaches. In Engineering Secure Software and Systems; Barthe, G., Livshits, B., Scandariato, R., Eds.; Springer: Berlin/Heidelberg, Germany, 2012; pp. 14–21. [Google Scholar]
- Dhillon, G. Managing Information System Security; M.P. Ltd., Ed.; Palgrave Macmillan: London, UK, 1997. [Google Scholar]
- Kemmerer, R.A. Cybersecurity. In Proceedings of the 25th International Conference on Software Engineering, Portland, OR, USA, 10 May 2003.
- Baskerville, R. The development duality of information systems security. J. Manage. Syst. 1992, 4, 1–12. [Google Scholar]
- McDermott, J.; Fox, C. Using Abuse Case Models for Security Requirements Analysis. In Proceedings of the 15th Annual Computer Security Applications Conference, Phoenix, AZ, USA, 6–10 December 1999.
- Anderson, C. The Long Tail: How Endless Choice Is Creating Unlimited Demand; Random House Business Books: London, UK, 2006. [Google Scholar]
- Householder, A.; Houle, K.; Dougherty, C. Computer attack trends challenge Internet security. IEEE Comput. 2002, 35, 5–7. [Google Scholar] [CrossRef]
- James, H.L. Managing information systems security: A soft approach. In Proceedings of the Information Systems Conference of New Zealand, Palmerston North, New Zealand, 30–31 October 1996.
- Papazafeiropoulou, A.; Pouloudi, A. The Government’s Role in Improving Electronic Commerce Adoption. In Proceedings of the European Conference on Information Systems 2000 Conference, Wienna, Austria, 3–5 July 2000.
- Dimopoulos, V.; Furnell, S.; Jennex, M.; Kritharas, I. Approaches to IT Security in Small and Medium Enterprises. In Proceedings of the 2nd Australian Information Security Management Conference, Securing the Future, Perth, Australia, 26 November 2004; pp. 73–82.
- Gupta, A.; Hammond, R. Information systems security issues and decisions for small businesses. Inf. Manage. Comput. Secur. 2005, 13, 297–310. [Google Scholar] [CrossRef]
- Helokunnas, T.; Iivonen, L. Information Security Culture in Small and Medium Size Enterprises. In e-Business Research Forum—eBRF 2003; Tampere University of Technology: Tampere, Finland, 2003. [Google Scholar]
- ISBS. Information Security Breaches Survey 2006; Department of Trade and Industry: London, UK, 2006. [Google Scholar]
- Furnell, S.M.; Gennatou, M.; Dowland, P.S. Promoting Security Awareness and Training within Small Organisations. In Proceedings of the 1st Australian Information Security Management Workshop, Deakin University, Geelong, Australia, 7 November 2000.
- Johnson, D.W.; Koch, H. Computer Security Risks in the Internet Era: Are Small Business Owners Aware and Proactive? In Proceedings of the 39th Annual Hawaii International Conference on System Sciences (HICSS'06), Maui, HI, USA, 4–7 January 2006.
- O’Halloran, J. ICT business management for SMEs. Comput. Wkly. Available online: http://www.computerweekly.com/feature/ICT-business-management-for-SMEs (accessed on 4 June 2016).
- Doherty, N.F.; Fulford, H. Aligning the Information Security Policy with the Strategic Information Systems Plan. Comput. Secur. 2006, 25, 55–63. [Google Scholar] [CrossRef] [Green Version]
- Seaman, C.B. Qualitative Methods in Empirical Studies of Software Engineering. IEEE Trans. Softw. Eng. 1999, 25, 557–572. [Google Scholar] [CrossRef]
- Avison, D.; Lau, F.; Myers, M.D.; Nielsen, P.A. Action research. Commun. ACM 1999, 42, 94–97. [Google Scholar] [CrossRef]
- Genero, M.; Cruz-Lemus, J.A.; Piattini, M. Métodos de Investigación en Ingeniería del Software; Editorial RA-MA: Madrid, Spain, 2014; pp. 171–199. [Google Scholar]
- Bugdol, M.; Jedynak, P. Integration of Standardized Management Systems, In Integrated Management Systems; Springer: Cham, Switzerland, 2015; pp. 129–160. [Google Scholar]
- Bugdol, M.; Jedynak, P. Integrated Management Systems; Springer: Cham, Switzerland, 2015. [Google Scholar]
- International Organization for Standardization. ISO/IEC 27001:2013, Information Technology—Security Techniques Information Security Management Systemys—Requirements; International Organization for Standardization: Geneva, Switzerland, 2013. [Google Scholar]
- International Organization for Standardization. ISO/IEC 27002:2013, the International Standard Code of Practice for Information Security Management (en desarrollo); International Organization for Standardization: Geneva, Switzerland, 2013. [Google Scholar]
- COBIT 5. Cobit Guidelines, Information Security Audit and Control Association; ISACA: Rolling Meadows, IL, USA, 2012. [Google Scholar]
- Batista, J.; Figueiredo, A. SPI in very small team: A case with CMM. Softw. Process Improv. Pract. 2000, 5, 243–250. [Google Scholar] [CrossRef]
- Hareton, L.; Terence, Y. A Process Framework for Small Projects. Softw. Process Improv. Pract. 2001, 6, 67–83. [Google Scholar]
- Tuffley, A.; Grove, B.; McNair, G. SPICE for Small Organisations. Softw. Process Improv. Pract. 2004, 9, 23–31. [Google Scholar] [CrossRef]
- Villalon, J.A.C.M.; Agustin, G.C.; Gilabert, T.S.F.; Seco, A.D.A.; Sanchez, L.G.; Cota, M.P. Experiences in the Application of Software Process Improvement in SMES. Softw. Qual. J. 2004, 10, 261–273. [Google Scholar] [CrossRef]
- Mekelburg, D. Sustaining Best Practices: How Real-World Software Organizations Improve Quality Processes. Softw. Qual. Prof. 2005, 7, 4–13. [Google Scholar]
- Sánchez, L.E.; Santos-Olmo, A.; Fernández-Medina, E.; Piattini, M. ISMS Building for SMEs through the Reuse of Knowledge. In Small Medium Enterprises: Concepts, Methodologies, Tools, Applications; IGI Global: Hershey, PA, USA, 2013; p. 394. [Google Scholar]
- Sánchez, L.E.; Parra, A.S.O.; Rosado, D.G.; Piattini, M. Managing Security and its Maturity in Small and Medium-sized Enterprises. J. Univers. Comput. Sci. 2009, 15, 3038–3058. [Google Scholar]
- Santos-Olmo, A.; Sánchez, L.E.; Fernández-Medina, E.; Piattini, M. Desirable Characteristics for an ISMS Oriented to SMEs. In Proceedings of 8th International Workshop on Security in Information Systems (ICEIS 2011), Beijing, China, 8–11 June 2011; pp. 151–158.
- Santos-Olmo, A.; Sánchez, L.E.; Fernández-Medina, E.; Piattini, M. A Systematic Review of Methodologies and Models for the Analysis and Management of Associative and Hierarchical Risk in SMEs. In Proceedings of the 9th International Workshop on Security in Information Systems (WOSIS12), Wroclaw, Poland, 28 June 2012; pp. 117–124.
- Sánchez, L.E.; Santos-Olmo, A.; Fernández-Medina, E.; Piattini, M. Building ISMS Through Knowledge Reuse. In Proceedings of the 7th International Conference on Trust, Privacy & Security in Digital Business (TRUSTBUS'10), Bilbao, Spain, 30–31 August 2010.
- Sánchez, L.E.; Santos-Olmo, A.; Fernández-Medina, E.; Piattini, M. Security Culture in Small and Medium-Size Enterprise, In ENTERprise Information Systems; Springer: Berlin/Heidelberg, Germany, 2010; pp. 315–324. [Google Scholar]
Cycle | Weeks | Consultantation Effort Hours | Consultant Time Cost (€) | Customer Personnel Effort Hours | Customer Personnel Time Cost (€) | Total Consultation Cost (€) | Total Cost to Customer (€) | Total Cost of Project (€) |
---|---|---|---|---|---|---|---|---|
I1 | 48 | 960 | 50 | 2880 | 20 | 48,000 | 57,600 | 105,600 |
I2 | 44 | 704 | 50 | 2464 | 20 | 35,200 | 49,280 | 84,480 |
I3 | 42 | 622 | 50 | 2184 | 20 | 31,080 | 43,680 | 74,760 |
I4 | 39 | 577 | 50 | 1794 | 20 | 28,860 | 35,880 | 64,740 |
I5 | 31 | 446 | 50 | 1364 | 20 | 22,320 | 27,280 | 49,600 |
I6 | 28 | 403 | 50 | 1176 | 20 | 20,160 | 23,520 | 43,680 |
I7 | 26 | 364 | 50 | 1144 | 20 | 18,200 | 22,880 | 41,080 |
I8 | 18 | 230 | 50 | 684 | 20 | 11,520 | 13,680 | 25,200 |
I9 | 20 | 272 | 50 | 840 | 20 | 13,600 | 16,800 | 30,400 |
I10 | 21 | 277 | 50 | 756 | 20 | 13,860 | 15,120 | 28,980 |
I11 | 17 | 218 | 50 | 612 | 20 | 10,880 | 12,240 | 23,120 |
I12 | 17 | 211 | 50 | 544 | 20 | 10,540 | 10,880 | 21,420 |
I13 | 15 | 180 | 50 | 450 | 20 | 9000 | 9000 | 18,000 |
Description of Activity (Mod-I13) | Hours |
---|---|
Pre-audit | 16 |
Identification of assets | 8 |
Risk Analysis and Management | 24 |
Security Culture Course | 8 |
Training regulation domains (14) | 14 |
Consultation domains for the regulation. | 49 |
Literal Training in the regulation | 4 |
Literal consultation as regards the regulation. | 25 |
Review and validation of documentation. | 16 |
Internal audit | 16 |
Cycle | Internal Effort Hours/Month | Failure Rate | Customer Personnel Time Cost (€) | Total Cost to Customer (€) |
---|---|---|---|---|
M1 | 150 | 80 | 20 | 3000 |
M2 | 135 | 75 | 20 | 2700 |
M3 | 105 | 60 | 20 | 2100 |
M4 | 68 | 30 | 20 | 1350 |
M5 | 45 | 20 | 20 | 900 |
© 2016 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC-BY) license (http://creativecommons.org/licenses/by/4.0/).
Share and Cite
Santos-Olmo, A.; Sánchez, L.E.; Rosado, D.G.; Fernández-Medina, E.; Piattini, M. Applying the Action-Research Method to Develop a Methodology to Reduce the Installation and Maintenance Times of Information Security Management Systems. Future Internet 2016, 8, 36. https://doi.org/10.3390/fi8030036
Santos-Olmo A, Sánchez LE, Rosado DG, Fernández-Medina E, Piattini M. Applying the Action-Research Method to Develop a Methodology to Reduce the Installation and Maintenance Times of Information Security Management Systems. Future Internet. 2016; 8(3):36. https://doi.org/10.3390/fi8030036
Chicago/Turabian StyleSantos-Olmo, Antonio, Luis Enrique Sánchez, David G. Rosado, Eduardo Fernández-Medina, and Mario Piattini. 2016. "Applying the Action-Research Method to Develop a Methodology to Reduce the Installation and Maintenance Times of Information Security Management Systems" Future Internet 8, no. 3: 36. https://doi.org/10.3390/fi8030036
APA StyleSantos-Olmo, A., Sánchez, L. E., Rosado, D. G., Fernández-Medina, E., & Piattini, M. (2016). Applying the Action-Research Method to Develop a Methodology to Reduce the Installation and Maintenance Times of Information Security Management Systems. Future Internet, 8(3), 36. https://doi.org/10.3390/fi8030036