Optimising the Preparedness Capacity of Enterprise Resilience Using Mathematical Programming
Abstract
:1. Introduction
2. Literature Foundations
- Disruption characterisationThis section, based on the categorisation framework of disruption defined in [37], is in turn composed of the following:
- Source, divided into (i) the level at which the disruptive event originated and (ii) the origin and suborigin of the disruptive event. More information can be found in [38].
- Disruptive event per se, considered as a situation that causes a disturbance to a company’s daily operations. The framework contains 71 of the most common disruptive events suffered by companies.
- Consequences, which are a set of related effects that a specific disruptive event occurrence may cause.
- Constituent capacityIn order to deal with the negative effects of disruptions, companies should be as resilient as possible. To accomplish this, the framework is focused on three main capacities of enterprise resilience:
- Preparedness: the readiness capacity to face disruptions, assessing whether companies have the knowledge, means and resources to be able to anticipate different disruptions [39].
- Adaptivity: defined as the degree to which the system can modify its circumstances and move towards a condition of stability [40]. Sandanam et al. [41] defined it as the capacity to respond to challenges through learning, managing risk and impacts, developing knowledge, and devising novel solutions. The dynamic nature of adaptive capacity allows companies to be prepared in advance and recover after having been impacted by a disruptive event. Following [42], the dynamism of adaptive capacity is the reason why it is considered in the framework as an intrinsic characteristic of the capacities of preparedness and recovery and not a constituent capacity, per se, of enterprise resilience.
- Recovery: the ability to respond to and bounce back from a disruptive situation, which is key to bolstering enterprise resilience.
- Transition elementsIn order to enhance preparedness and recovery capacities, companies need to take different actions. In the first case, the framework proposes preventive actions as proactive mechanisms to face inevitable disruptive events. In the second case, the framework points to knowledge management to guarantee that the necessary knowledge is available to be reused when necessary and facilitate the recovery process.
- Preventive actions are policies and/or actions that are carried out in an attempt to reduce the probability of the occurrence or severity of a disruptive event or both [20]. They are proactive by nature. In case of inevitable disruptive events, effort should be focused on mitigating the negative consequences.
- Regarding knowledge registration actions, Dalziell et al. [9] explained that one of the ways in which a system can recover from adverse situations is to apply available responses to deal with disruptive events. To do so, profound knowledge of the available responses to disruptive events that have already occurred is required in order to reuse the knowledge generated in past recovery actions.
3. Data Modelling Approach
3.1. Data Definition
3.1.1. Definition of Input Data Required to Analyse the AS IS State
3.1.2. Definition of Input Data Required to Analyse TO BE Situation
3.2. Nomenclature Definitions
3.3. Data Processing
4. Mixed-Integer Linear Programming Model
5. Application to a Foam Company
5.1. Input Data
5.2. Implementation and Resolution
5.3. Evaluation of Results
6. Conclusions and Further Research
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
#D | Temporal Horizon | Probability (AS IS) | Severity (AS IS) | #A | Probability (TO BE) | Severity (TO BE) | ||||||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
S | M | L | VL | L | M | H | VH | VL | L | M | H | VH | VL | L | M | H | VH | VL | L | M | H | VH | ||
S1 | X | X | X | S1.1 | X | X | ||||||||||||||||||
S1.2 | X | X | ||||||||||||||||||||||
S1.3 | X | X | ||||||||||||||||||||||
S1.4 | X | X | ||||||||||||||||||||||
S1.5 | X | X | ||||||||||||||||||||||
S1.6 | X | X | ||||||||||||||||||||||
S2 | X | X | X | S2.1 | X | X | ||||||||||||||||||
S2.2 | X | X | ||||||||||||||||||||||
S2.3 | X | X | ||||||||||||||||||||||
S2.4 | X | X | ||||||||||||||||||||||
S3 | X | X | X | S3.1 | X | X | ||||||||||||||||||
S3.2 | X | X | ||||||||||||||||||||||
S3.3 | X | X | ||||||||||||||||||||||
S4 | X | X | X | S4.1 | X | X | ||||||||||||||||||
S4.2 | X | X | ||||||||||||||||||||||
S4.3 | X | X | ||||||||||||||||||||||
S4.4 | X | X | ||||||||||||||||||||||
S5 | X | X | X | S5.1 | X | X | ||||||||||||||||||
S5.2 | X | X | ||||||||||||||||||||||
S5.3 | X | X | ||||||||||||||||||||||
S5.4 | X | X | ||||||||||||||||||||||
S6 | X | X | X | S6.1 | X | X | ||||||||||||||||||
S6.2 | X | X | ||||||||||||||||||||||
S6.3 | X | X | ||||||||||||||||||||||
S6.4 | X | X | ||||||||||||||||||||||
S7 | X | X | X | S7.1 | X | X | ||||||||||||||||||
S7.2 | X | X | ||||||||||||||||||||||
S7.3 | X | X | ||||||||||||||||||||||
ET1 | X | X | X | ET1.1 | X | X | ||||||||||||||||||
ET1.2 | X | X | ||||||||||||||||||||||
ET1.3 | X | X | ||||||||||||||||||||||
ET1.4 | X | X | ||||||||||||||||||||||
ET1.5 | X | X | ||||||||||||||||||||||
ET2 | X | X | X | ET2.1 | X | X | ||||||||||||||||||
ET2.2 | X | X | ||||||||||||||||||||||
ET2.3 | X | X | ||||||||||||||||||||||
ET3 | X | X | X | ET3.1 | X | X | ||||||||||||||||||
ET3.2 | X | X | ||||||||||||||||||||||
ET3.3 | X | X | ||||||||||||||||||||||
ET4 | X | X | X | ET4.1 | X | X | ||||||||||||||||||
ET4.2 | X | X | ||||||||||||||||||||||
ET4.3 | X | X | ||||||||||||||||||||||
ET4.4 | X | X | ||||||||||||||||||||||
ET4.5 | X | X | ||||||||||||||||||||||
ET5 | X | X | X | ET5.1 | X | X | ||||||||||||||||||
ET5.2 | X | X | ||||||||||||||||||||||
ET5.3 | X | X | ||||||||||||||||||||||
ET5.4 | X | X | ||||||||||||||||||||||
ET6 | X | X | X | ET6.1 | X | X | ||||||||||||||||||
ET6.2 | X | X | ||||||||||||||||||||||
ET6.3 | X | X | ||||||||||||||||||||||
ET7 | X | X | X | ET7.1 | X | X | ||||||||||||||||||
ET7.2 | X | X | ||||||||||||||||||||||
ET7.3 | X | X | ||||||||||||||||||||||
ET7.4 | X | X | ||||||||||||||||||||||
F1 | X | X | X | F1.1 | X | X | ||||||||||||||||||
F1.2 | X | X | ||||||||||||||||||||||
F1.3 | X | X | ||||||||||||||||||||||
F1.4 | X | X | ||||||||||||||||||||||
F2 | X | X | X | F2.1 | X | X | ||||||||||||||||||
F2.2 | X | X | ||||||||||||||||||||||
F2.3 | X | X | ||||||||||||||||||||||
F3 | X | X | X | F3.1 | X | X | ||||||||||||||||||
F3.2 | X | X | ||||||||||||||||||||||
F3.3 | X | X | ||||||||||||||||||||||
F4 | X | X | X | F4.1 | X | X | ||||||||||||||||||
F4.2 | X | X | ||||||||||||||||||||||
F4.3 | X | X | ||||||||||||||||||||||
F4.4 | X | X | ||||||||||||||||||||||
L1 | X | X | X | L1.1 | X | X | ||||||||||||||||||
L1.2 | X | X | ||||||||||||||||||||||
L1.3 | X | X | ||||||||||||||||||||||
L1.4 | X | X | ||||||||||||||||||||||
L1.5 | X | X | ||||||||||||||||||||||
L2 | X | X | X | L2.1 | X | X | ||||||||||||||||||
L2.2 | X | X | ||||||||||||||||||||||
L2.3 | X | X | ||||||||||||||||||||||
L2.4 | X | X | ||||||||||||||||||||||
L2.6 | X | X | ||||||||||||||||||||||
L3 | X | X | X | L3.1 | X | X | ||||||||||||||||||
L3.2 | X | X | ||||||||||||||||||||||
L3.3 | X | X | ||||||||||||||||||||||
L3.4 | X | X |
#D | Iteration 1 | Iteration 2 | Iteration 3 | Iteration 4 | Iteration 5 | |||||
---|---|---|---|---|---|---|---|---|---|---|
CDi | Ai | CDi | Ai | CDi | Ai | CDi | Ai | CDi | Ai | |
1 | 0 | 21,989 | 2767 | 16,583 | 2767 | 16,583 | 2767 | 16,583 | 2767 | 16,583 |
2 | 997 | 353 | 997 | 353 | 997 | 353 | 997 | 353 | 997 | 353 |
3 | 452 | 2248 | 452 | 2248 | 452 | 2248 | 452 | 2248 | 452 | 2248 |
4 | 3172 | 3128 | 3172 | 3128 | 3172 | 3128 | 3172 | 3128 | 3172 | 3128 |
5 | 6644 | 15,006 | 6644 | 15,006 | 6644 | 15,006 | 6644 | 15,006 | 6644 | 15,006 |
6 | 0 | 1055 | 278 | 588 | 278 | 588 | 278 | 588 | 278 | 588 |
7 | 1032 | 0 | 1032 | 1032 | 0 | 1032 | 0 | 1032 | 0 | |
8 | 5070 | 66,930 | 23,918 | 48,082 | 23,918 | 48,082 | 23,918 | 48,082 | 23,918 | 48,082 |
9 | 1935 | 0 | 1935 | 0 | 1935 | 0 | 1935 | 0 | 1935 | 0 |
10 | 12,367 | 27,683 | 20,167 | 19,883 | 20,167 | 19,883 | 20,167 | 19,883 | 20,167 | 19,883 |
11 | 1228 | 171,972 | 0 | 187,186 | 0 | 187,186 | 0 | 242,462 | 3860 | 169,340 |
12 | 768 | 107,482 | 768 | 107,482 | 54,509 | 53,741 | 54,509 | 53,741 | 54,509 | 53,741 |
13 | 13,500 | 18,975 | 0 | 45,375 | 3229 | 29,246 | 6075 | 26,400 | 3229 | 29,246 |
14 | 3031 | 0 | 3031 | 0 | 3031 | 0 | 3031 | 0 | 3031 | 0 |
15 | 2362 | 4088 | 6450 | 0 | 2362 | 4088 | 6450 | 0 | 2362 | 4088 |
16 | 12,015 | 0 | 12,015 | 0 | 12,015 | 0 | 12,015 | 0 | 12,015 | 0 |
17 | 5160 | 0 | 5160 | 0 | 5160 | 0 | 5160 | 0 | 5160 | 0 |
18 | 151 | 15,974 | 5451 | 10,674 | 4656 | 11,469 | 5451 | 10,674 | 4656 | 11,469 |
19 | 1784 | 7891 | 1784 | 7891 | 1784 | 7891 | 1784 | 7891 | 1784 | 7891 |
20 | 6496 | 6404 | 6496 | 6404 | 92 | 12,808 | 92 | 12,808 | 6496 | 6404 |
21 | 5846 | 5764 | 5846 | 5764 | 5846 | 5764 | 0 | 13,449 | 5846 | 5764 |
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Reference | Approach Orientation | Scope | |
---|---|---|---|
Woods et al. [13] | Conceptual Framework | Enterprise | |
Approach | This approach is based on the principle that in order to achieve resilience, organizations need support for decisions about production/safety trade-offs. Enterprises require mechanisms to analyse when to relax the pressure on throughput and efficiency goals, i.e., making a sacrifice decision; how to help organizations decide when to relax production pressure to reduce vulnerability. To do so, the authors point out the following aspects: (i) Management commitment, (ii) Reporting culture, (iii) Learning culture, (iv) Preparedness/Anticipation, (v) Flexibility and (vi) Opacity (and its corollary, Observability). | ||
Limitation | L1. Conceptual approach, not practically implementable. | ||
Dalziell et al. [9] | Indicators | Enterprise | |
Approach | The authors explain that resilience is a function of the vulnerability and adaptive capacity of the company. They use a systematic view of the company and state that one of the key aspects that defined a system is its purpose. Therefore, since a company is a system, the authors directly relate its resilience capacity with the ability to achieve its objectives and purposes. Companies usually map their mission through a series of key performance indicators (KPIs). The ease with which key performance indicators can drift to undesirable levels of instability is a function of the vulnerability of the system. Furthermore, the time it takes for such performance indicators to recover and achieve resilience is a function of the adaptive capacity. | ||
Limitation | L2. Excessive specificity of the approach. The definition of KPIs based on the mission of the company means that each company has different measurable metrics. This characteristic implies that each enterprise deals with the resilience enhancement in a different way. | ||
McManus et al. [14] | Indicators/Methodology | Enterprise | |
Approach | This approach considers that the resilience of an organization involves three main axes: (i) situation awareness, (ii) management of the keystone vulnerabilities of an organization and (iii) the adaptive capacity. Based on these three main pillars, the authors develop the model called Relative Overall Resilience, by defining 15 indicators to assess resilience capacity. An extended version of this study may be found in Lee et al. [15]. | ||
Limitations | L2. Excessive specificity of the approach. The 15 indicators used to assess enterprise resilience are defined through case studies of organizations. For this reason, the generalizability of the research results is limited to the organizations participating in these case studies. L3. Resilience assessment but not enhancement. This approach offers information about the resilience profile of a company, but it does not offer any additional information regarding how to improve enterprise resilience. | ||
Falasca et al. [16] | Indicators | Supply chain | |
Approach | A simulation-based framework that incorporates the following three determinants of resilience: density, complexity, and node criticality into the process of supply chain design. An updated research related to this area was carried out by Kim et al. [17], who propose a set of a metrics for supply network resilience in terms of the total number of node/arc disruptions. | ||
Limitations | L4. Lack of optimisation It does not incorporate cost data into the agents’ decision-making function, thus limiting the possibilities of performing relevant trade-off analyses. The approach tests supply chain responses to different strategies for improving. disaster resilience but it does not look at the determination of an “optimal” strategy under different conditions. | ||
Stolker et al. [18] | Indicators | Enterprise | |
Approach | This attempt applies multi-attribute utility theory to measure the management performance of operational resilience in an organization. The approach analyses some elements such as: understanding mission-critical processes, risk management performance, reward system, and cultural aspects. | ||
Limitations | L4. Lack of optimisation. | ||
Erol et al. [19] | Conceptual Framework | Supply chain | |
Approach | Conceptual framework focused on extended enterprises and based on the key attributes of enterprise resilience: agility, flexibility, adaptability, interoperability and connectivity. Achieving resilience requires the application of two enablers: (i) the capability of an enterprise to become more connected and responsive to the environment, stakeholders and competitors; and (ii) the alignment of information technology with business goals. | ||
Limitations | L1. Conceptual approach, not practically implementable. | ||
Barroso et al. [20] | Methodology/Indicators | Supply Chain | |
Approach | This approach defines a methodology to assess resilience in SCs through value stream mapping to offer a clear view and understanding of supply chain entities’ actual capabilities. Two performance measures are defined for the assessment: supply chain cost and lead time. | ||
Limitations | L2. Excessive specificity of the approach. This study only analyses a very particular case study. L3. Resilience assessment but not enhancement. This research assesses supply chain resilience; however, it does not suggest strategies to improve this capacity. | ||
Carvalho et al. [21] | Indicators/Methodology | Supply chain | |
Approach | This research uses a combination of simulation and a case study to design supply chains more resilient to disturbances. In this research, the simulation study is used to evaluate the effects of strategies on the behaviour of some entities of a Portuguese automotive supply chain and to explore if the strategies are effective in overcoming the negative effects of the disturbance: “supply delay”. | ||
Limitation | L2. Excessive specificity of the approach. | ||
Cabral et al. [22] | Indicators | Enterprise/Supply chain | |
Approach | This approach proposes an integrated lean, agile, resilient and green analytic network process model to support decision-making in choosing the most appropriate practices and KPIs to be implemented by companies in a supply chain. | ||
Limitation | L2. Excessive specificity of the approach. Limited number of practices and KPIs. | ||
Soni et al. [23] | Indicators | Supply chain | |
Approach | This research proposes a model using graph theory which holistically considers all the major enablers of resilience (supply chain agility, collaboration among players, information sharing, sustainability in supply chain, risk and revenue sharing, trust among players, supply chain visibility, creating risk management culture, adaptive capability and supply chain structure) and their interrelationships for analysis using an interpretive structural modeling approach. | ||
Limitation | L3. Resilience assessment but not enhancement. L4. Lack of optimisation The approach quantifies resilience by a single numerical index but it does not offer insights about how to enhance resilience and which are the best strategies to achieve it. | ||
Munoz et al. [24] | Indicators | Supply chain | |
Approach | Proposal of a model to assess a set of metrics for operational supply chain resilience in terms of recovery, impact, performance loss, profile length, and weighted-sum. | ||
Limitation | L2. Excessive specificity of the approach. This approach is limited in scope to a serial three-tier supply chain with no backlog. |
Limitations | Progress Beyond the SoA |
---|---|
L1. Conceptual approach, not practically implementable. | This research defines a simple but effective MILP that can be applied without difficulty in any enterprise. The mathematical formulation has been proposed from a management and business perspective in order to make it as simple and comprehensible as possible so that it does not require highly mathematically skilled personnel, thus allowing top managers to apply it easily. Moreover, a pilot case study has been performed in a real company to validate the mathematical formulation and to show how the mathematical formulation could be applied. |
L2. Excessive specificity of the approach. | The present research is based on Sanchis et al. [12] framework that encompasses 71 disruptive events that enterprises consider as threats to their continuity. Moreover, the current version of the framework also provides a set of 403 preventive actions from among whom to choose the most adequate actions to prepare in advance for disruptive events. The framework has been defined as a living approach. New disruptive events and preventive actions that companies wish to analyse may be included whenever required. Besides, it is important to highlight the generality of the approach taken in this research that allows it to be applied to any type of company, of any size and sector. Finally, the mathematical formulation offers a generic and easy-to-use mechanism to guarantee that it can be applied effortlessly. |
L3. Resilience assessment but not enhancement. | Most of the studies found in the literature review are mainly focused on measuring how resilient organisations are, but they do not offer guidelines and/or recommendations on how to enhance the resilience capacity. The present research optimises the activation of a set of preventive actions that enhance the preparedness capacity to reduce enterprises’ proneness to disruptions and offers valuable information to support enterprises in their decision-making process aimed at becoming more resilient. |
L4. Lack of optimisation |
AS IS Situation | Description |
---|---|
Probability of occurrence of disruptive event | The likelihood that a disruptive event will occur. Enterprises have to estimate the probability of occurrence according to a 5-level Likert scale (very high (VH), high (H), medium (M), low (L), and very low (VL)). Based on studies performed by Lichtenstein and Newman [58], Moore [59], Boehm [60], Hamm [61], Conrow [62] and Hillson [63], whose main aim was to determine the numerical values for each scale range, the present research uses values proposed in [63]: VH, 80.1%; H, 64.5%; M, 43.3%; L, 18%; and VL, 8.1%. |
Temporal horizon | The time horizon, defined as a future point in time when the occurrence of disruptive events will be evaluated. In this research, three temporal horizons are considered: long-term (more than 10 years), medium-term (between 5 and 10 years, average 5 years) and short-term (next year). Quantification of the time horizon is used to differentiate between more and less habitual disruptive events at the same probability level. |
Severity of disruptive event | The most likely consequences of a potential disruptive event. In other words, the harshness assigned to the consequences if a specific disruptive event materializes. Severity is assessed through a 5-level Likert scale in the same way as probability of occurrence. In light of this, the numerical values of severity levels are based on previous works developed by Fine [64], Dickson [65], Romero et al. [66] and Smith [67]. In this research, the values for severity are the averages defined by Patterson and Neailey [68]: VH, 95.5%; H, 70.5%; M, 35.5%; L, 13.0%; and VL, 2.5%. |
Annual cost of disruptive event | The monetary amount that it would cost if a specific disruptive event materialised. If the company is working at a normal level of operation and a disruptive event occurs, this cost is the amount of money that the company will have to invest to return from the unstable state to the normal state of operation. Users of the questionnaire provide this piece of information as a percentage of annual turnover. |
TO BE Situation | Description |
---|---|
Decreased probability of occurrence/severity of disruptive event | The main goal of implementing preventive actions is to diminish the probability of occurrence and/or the severity of disruptive events. Therefore, it is necessary to estimate the new range to which the probability and severity are reduced in order to quantify the improvement after such actions. |
Annual cost of preventive actions | The annual cost of implementing/activating a specific preventive action. The following assumptions are considered with regard to preventive actions:
|
Indices | |
---|---|
i | Disruptive events that may potentially occur |
j | Preventive actions for enhancing preparedness capacity to face disruptive events |
Parameters | |
Pi | Probability of disruptive event i occurring in the time horizon |
Pij | Probability of disruptive event i occurring after implementing preventive action j in the time horizon |
Hi | Time horizon for estimating the occurrence of disruptive event i (years) |
Si | Severity of disruptive event i |
Sij | Severity of disruptive event i after implementing preventive action j |
T | Annual turnover (€) |
PCTi | Cost of disruptive event i as % of annual turnover if it occurs |
PCTj | Cost of preventive action j as % of annual turnover |
Rij | Binary parameter that relates disruptive event i and preventive action j |
Ci | Expected annual cost of disruptive event i (€) |
Cj | Annual cost of preventive action j (€) |
Cij | Expected annual cost of disruptive event i after implementing preventive action j (€) |
Aij | Annual savings by implementing preventive action j for disruptive event i (€) |
Decision variables | |
Ej | Binary variable indicating whether preventive action j is activated or not (1 if activated, 0 if not) |
CDi | Expected annual cost of disruptive event i after implementing one or several preventive actions j (€) |
Ai | Annual savings by activating one or several preventive actions for disruptive event i (€). |
#D | Disruptive Event | #A | Preventive Actions |
---|---|---|---|
S1 | Poor quality of raw materials or components supplied | S1.1 | Search for alternative raw materials or components |
S1.2 | Search for alternative suppliers | ||
S1.3 | Certify (audit) supplier quality | ||
S1.4 | Implement quality systems agreed with suppliers | ||
S1.5 | Conduct pre-production inspection | ||
S1.6 | Maintain safety stock | ||
S2 | Limiting changes in capacity of suppliers | S2.1 | Search for alternative suppliers |
S2.2 | Define long-term contractual agreements with suppliers | ||
S2.3 | Implement continuous monitoring systems of suppliers/materials | ||
S2.4 | Adopt backward vertical integration | ||
S3 | Geographic dispersion of suppliers (time difference, language, proximity) | S3.1 | Search for alternative suppliers |
S3.2 | Promote closer relationships | ||
S3.3 | Implement real-time communication systems | ||
S4 | Delay in supply of raw materials or components | S4.1 | Implement penalties for delays |
S4.2 | Search for alternative suppliers | ||
S4.3 | Encourage collaborative work with suppliers and joint problem-solving to establish realistic replenishment systems | ||
S4.4 | Maintain safety stock | ||
S5 | Shortage of raw materials | S5.1 | Search for alternative raw materials or components |
S5.2 | Define new compositions of products | ||
S5.3 | Define complementary products that do not require scarce raw materials and replace current products | ||
S5.4 | Implement reverse logistics and recycling systems | ||
S6 | Price fluctuations of materials supplied | S6.1 | Analyse seasonality and trends (supply-demand balance) of raw material prices |
S6.2 | Search for alternative raw materials or components | ||
S6.3 | Search for alternative suppliers | ||
S6.4 | Closely monitor commodity markets; make strategic purchases | ||
S7 | Withdrawal of key supplier | S7.1 | Increase the supply base |
S7.2 | Partner with suppliers (temporary union of companies) | ||
S7.3 | Use vertical backward integration of all or part of the supply function |
#D | Disruptive Event | #A | Preventive Actions |
---|---|---|---|
ET1 | Fire | ET1.1 | Train personnel on security measures for fire protection |
ET1.2 | Ensure constant revision and maintenance of fire hoses | ||
ET1.3 | Maintain insurance contracts that include anti-fire clauses | ||
ET1.4 | Implement anti-fire measures | ||
ET1.5 | Conduct periodic fire drills | ||
ET2 | Increase of competitors | ET2.1 | Conduct periodic analysis of the competition |
ET2.2 | Use benchmarking | ||
ET2.3 | Define differentiation strategies from competitors | ||
ET3 | Entry of new competitors in emerging countries | ET3.1 | Analyse potential patents and intellectual property rights to protect products/processes of focal firm |
ET3.2 | Define policies that foster creation of high reputation and brand loyalty of focal firm | ||
ET3.3 | Define product differentiation policies | ||
ET4 | Facilities are exposed to severe natural disasters | ET4.1 | Define business continuity plans |
ET4.2 | Define emergency evacuation protocols | ||
ET4.3 | Train personnel in security measures for protection | ||
ET4.4 | Conduct periodic drills | ||
ET4.5 | Simulate disaster scenarios and establish specific measures based on simulation results | ||
ET5 | Geopolitical instability in countries where enterprise has facilities | ET5.1 | Define a structured, analytical and comparative approach to potential political changes and government policies around the world |
ET5.2 | Define and analyse indicators related to degree of uncertainty in strategic countries that could lead to adverse changes in operations of focal firm | ||
ET5.3 | Conduct strategic planning regarding locations of new facilities of focal firm considering the situation of governments in such countries | ||
ET5.4 | Simulate geopolitical scenarios and establish specific measures based on simulation results | ||
ET6 | Industrial espionage | ET6.1 | Define policies to periodically change passwords and protocols that allow access to different levels of information |
ET6.2 | Define employment contracts with formal descriptions of activities that can be considered as espionage (or may favour it due to the absence of due diligence) and specify consequences for workers | ||
ET6.3 | Have specific and constantly updated protection programs (anti-spyware, antivirus, firewall) | ||
ET7 | Sabotage, theft, vandalism, kidnapping and extortion | ET7.1 | Develop educational programme for physical protection of facilities |
ET7.2 | Control and register dissatisfied employees or those who often have a negative attitude against regulations established by focal firm | ||
ET7.3 | Establish policies to promote satisfaction of personnel of focal firm | ||
ET7.4 | Establish efficient system of identifying, registering and controlling persons, packages and vehicles |
#D | Disruptive Event | #A | Preventive Actions |
---|---|---|---|
F1 | Restricted access to credit | F1.1 | Create a reserve fund and define policies that maintain a percentage of monetary reserve |
F1.2 | Study the viability of turning to supply chain financing instruments | ||
F1.3 | Study and analyse policies supported by public institutions to fund companies (e.g., Official Credit Institute and Enisa in Spain) | ||
F1.4 | Request credit through reciprocal guarantee companies that act as guarantors of financing, assuming credit risks | ||
F2 | Changes in interest rates | F2.1 | Negotiate with banks on variable interest rate |
F2.2 | Study the advisability of investing in products with a fixed interest rate | ||
F2.3 | Study the advisability of investing in or asking for funding to foreign entities or currency (e.g., swiss franc - CHF) | ||
F3 | Changes in currency exchange rates | F3.1 | Define a standard conversion method to the reference currency when registering accounting information |
F3.2 | Define hedging strategies to neutralize or reduce the risk of exposure to fluctuations in exchange rates | ||
F3.3 | Sign contracts for future commercial transactions at an exchange rate agreed upon in the present | ||
F4 | Cash problems | F4.1 | Search for a sponsor |
F4.2 | Create reserve fund and define policies that maintain a percentage of monetary reserve | ||
F4.3 | Study the viability of turning to supply chain financing instruments | ||
F4.4 | Provide inventory liquidation with discount |
#D | Disruptive Event | #A | Preventive Actions |
---|---|---|---|
L1 | New and more restrictive legislation of imports/exports | L1.1 | Design and develop flexible, fast and easily reconfigurable processes |
L1.2 | Design and develop easily adaptable products that meet the most stringent requirements of new regulations (weight, composition, presentation, identification, labelling) | ||
L1.3 | Participate in lobbying activities exerting pressure to influence decisions about legislation | ||
L1.4 | Monitor import and export trade regimes constantly | ||
L1.5 | Monitor countries under embargo constantly and study alternatives for such countries | ||
L2 | Changes in legislation involving changes in company processes | L2.1 | Train employees in legal issues |
L2.2 | Define and implement publicity activities among customers about potential changes in the focal company’s processes from a positive approach; e.g., more environmentally friendly | ||
L2.3 | Design and develop flexible, fast and easily reconfigurable processes | ||
L2.4 | Implement continuous monitoring systems to control new or existing regulations/laws that could affect company’s processes | ||
L2.6 | Participate in lobbying activities exerting pressure to influence decisions about legislation | ||
L3 | Changes in legislation involving changes in our products | L3.1 | Train employees in legal issues |
L3.2 | Define and implement publicity activities among customers about potential changes in focal company’s products from a positive viewpoint; e.g., higher security | ||
L3.3 | Design and develop easily adaptable products that meet the most stringent requirements of new regulations (weight, composition, presentation, identification, labelling) | ||
L3.4 | Implement continuous monitoring systems to control new or existing regulations/laws that could potentially affect company’s products |
D | A | Preventive Action |
---|---|---|
S1, S5, S6 | S1.1, S5.1, S6.2 | Search for alternative raw materials or components |
S1, S2, S3, S4, S6 | S1.2, S2.1, S3.1, S4.2, S6.3 | Search for alternative suppliers |
S1, S4 | S1.6, S4.4 | Maintain safety stock |
ET1, ET4 | ET1.5, ET4.4 | Conduct periodic drills |
F1, F4 | F1.1, F4.2 | Create a reserve fund and define policies that maintain a percentage of monetary reserve |
F1.2, F4.3 | Study the viability of turning to supply chain financing instruments | |
L1, L2 | L1.1, L2.3 | Design and develop flexible, fast and easily reconfigurable processes |
L1.3, L2.6 | Participate in lobbying activities exerting pressure to influence decisions about legislation | |
L1, L3 | L1.2, L3.3 | Design and develop easily adaptable products that meet the most stringent requirements of new regulations (weight, composition, presentation, identification, labelling) |
L2, L3 | L2.1, L3.1 | Train employees in legal issues |
L2.2., L3.2 | Define and implement publicity activities among customers about potential changes in focal company’s processes/products from a positive approach |
Iteration 1 | Iteration 2 | Iteration 3 | Iteration 4 | Iteration 5 | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
# | #D | Ci | # | #A | Cj | Ej | CDi | Ej | CDi | Ej | CDi | Ej | CDi | Ej | CDi | |
1 | S1 | 30.000 | 19.350 | 1 | S1.1 | 950 | 1 | 0 | 1 | 2767 | 1 | 2767 | 1 | 2767 | 1 | 2767 |
2 | S1.2 | 900 | 1 | 1 | 1 | 1 | 1 | |||||||||
3 | S1.3 | 1500 | ||||||||||||||
4 | S1.4 | 3000 | ||||||||||||||
5 | S1.5 | 550 | ||||||||||||||
6 | S1.6 | 8000 | ||||||||||||||
2 | S2 | 7.500 | 1.350 | 2 | S2.1 | 900 | 1 | 997 | 1 | 997 | 1 | 997 | 1 | 997 | 1 | 997 |
7 | S2.2 | 500 | ||||||||||||||
8 | S2.3 | 1000 | ||||||||||||||
9 | S2.4 | 7250 | ||||||||||||||
3 | S3 | 15.000 | 2.700 | 2 | S3.1 | 900 | 1 | 452 | 1 | 452 | 1 | 452 | 1 | 452 | 1 | 452 |
10 | S3.2 | 800 | ||||||||||||||
11 | S3.3 | 1500 | ||||||||||||||
4 | S4 | 35.000 | 6.300 | 2 | S4.2 | 900 | 1 | 3172 | 1 | 3172 | 1 | 3172 | 1 | 3172 | 1 | 3172 |
6 | S4.4 | 8000 | ||||||||||||||
12 | S4.1 | 1500 | ||||||||||||||
13 | S4.3 | 2500 | ||||||||||||||
5 | S5 | 50.000 | 21.650 | 1 | S5.1 | 950 | 1 | 6644 | 1 | 6644 | 1 | 6644 | 1 | 6644 | 1 | 6644 |
14 | S5.2 | 6000 | ||||||||||||||
15 | S5.3 | 6800 | ||||||||||||||
16 | S5.4 | 5000 | ||||||||||||||
6 | S6 | 10.000 | 866 | 1 | S6.2 | 950 | 1 | 0 | 1 | 278 | 1 | 278 | 1 | 278 | 1 | 278 |
2 | S6.3 | 900 | 1 | 1 | 1 | 1 | 1 | |||||||||
17 | S6.1 | 500 | ||||||||||||||
18 | S6.4 | 1500 | ||||||||||||||
7 | S7 | 8.000 | 1.032 | 19 | S7.1 | 900 | 1032 | 1032 | 1032 | 1032 | 1032 | |||||
20 | S7.2 | 3000 | ||||||||||||||
21 | S7.3 | 7250 | ||||||||||||||
8 | ET1 | 400.000 | 72.000 | 22 | ET1.1 | 2000 | 1 | 5070 | 1 | 23,918 | 1 | 23,918 | 1 | 23,918 | 1 | 23,918 |
23 | ET1.2 | 4000 | ||||||||||||||
24 | ET1.3 | 20,000 | ||||||||||||||
25 | ET1.4 | 8000 | ||||||||||||||
26 | ET1.5 | 1500 | 1 | |||||||||||||
9 | ET2 | 15.000 | 1.935 | 27 | ET2.1 | 550 | 1935 | 1935 | 1935 | 1935 | 1935 | |||||
28 | ET2.2 | 400 | ||||||||||||||
29 | ET2.3 | 1500 | ||||||||||||||
10 | ET3 | 50.000 | 40.050 | 30 | ET3.1 | 8000 | 12,367 | 20,167 | 20,167 | 20,167 | 20,167 | |||||
31 | ET3.2 | 1.500 | 1 | 1 | 1 | 1 | 1 | |||||||||
32 | ET3.3 | 750 | 1 | |||||||||||||
11 | ET4 | 400.000 | 173.200 | 26 | ET4.4 | 1500 | 1228 | 0 | 0 | 0 | 3860 | |||||
33 | ET4.1 | 1500 | 1 | 1 | ||||||||||||
34 | ET4.2 | 1200 | 1 | |||||||||||||
35 | ET4.3 | 800 | 1 | 1 | 1 | |||||||||||
36 | ET4.5 | 1250 | 1 | 1 | 1 | 1 | ||||||||||
12 | ET5 | 250.000 | 108.250 | 37 | ET5.1 | 2000 | 1 | 768 | 768 | 54,509 | 54,509 | 54,509 | ||||
38 | ET5.2 | 2000 | 1 | |||||||||||||
39 | ET5.3 | 15,000 | ||||||||||||||
40 | ET5.4 | 1250 | 1 | 1 | 1 | 1 | 1 | |||||||||
13 | ET6 | 75.000 | 32.475 | 41 | ET6.1 | 1500 | 13,500 | 1 | 0 | 1 | 3229 | 1 | 6075 | 1 | 3229 | |
42 | ET6.2 | 350 | 1 | 1 | 1 | 1 | ||||||||||
43 | ET6.3 | 2000 | ||||||||||||||
14 | ET7 | 35.000 | 3.031 | 44 | ET7.1 | 500 | 3031 | 3031 | 3031 | 3031 | 3031 | |||||
45 | ET7.2 | 1000 | ||||||||||||||
46 | ET7.3 | 2500 | ||||||||||||||
47 | ET7.4 | 12,000 | ||||||||||||||
15 | F1 | 10.000 | 6.450 | 48 | F1.1 | 2500 | 2362 | 6450 | 2362 | 6450 | 2362 | |||||
49 | F1.2 | 800 | 1 | 1 | 1 | |||||||||||
50 | F1.3 | 800 | ||||||||||||||
51 | F1.4 | 1500 | ||||||||||||||
16 | F2 | 15.000 | 12.015 | 52 | F2.1 | 1500 | 12,015 | 12,015 | 12,015 | 12,015 | 12,015 | |||||
53 | F2.2 | 3000 | ||||||||||||||
54 | F2.3 | 2700 | ||||||||||||||
17 | F3 | 8.000 | 5.160 | 55 | F3.1 | 550 | 5160 | 5160 | 5160 | 5160 | 5160 | |||||
56 | F3.2 | 2000 | ||||||||||||||
57 | F3.3 | 1000 | ||||||||||||||
18 | F4 | 25.000 | 16.125 | 48 | F4.2 | 2500 | 151 | 5451 | 4656 | 5451 | 4656 | |||||
49 | F4.3 | 800 | 1 | 1 | 1 | |||||||||||
58 | F4.1 | 1000 | 1 | 1 | 1 | 1 | 1 | |||||||||
59 | F4.4 | 2500 | ||||||||||||||
19 | L1 | 15.000 | 9.675 | 60 | L1.1 | 8000 | 1784 | 1784 | 1784 | 1784 | 1784 | |||||
61 | L1.2 | 5000 | ||||||||||||||
62 | L1.3 | 2500 | ||||||||||||||
63 | L1.4 | 1000 | ||||||||||||||
64 | L1.5 | 550 | 1 | 1 | 1 | 1 | 1 | |||||||||
20 | L2 | 20.000 | 12.900 | 60 | L2.3 | 8000 | 6496 | 6496 | 92 | 92 | 6496 | |||||
62 | L2.6 | 2500 | ||||||||||||||
65 | L2.1 | 600 | 1 | 1 | 1 | 1 | 1 | |||||||||
66 | L2.2. | 2000 | 1 | 1 | ||||||||||||
67 | L2.4 | 1000 | 1 | |||||||||||||
21 | L3 | 18.000 | 11.610 | 61 | L3.3 | 5000 | 5846 | 5846 | 5846 | 0 | 5846 | |||||
65 | L3.1 | 600 | 1 | 1 | 1 | 1 | 1 | |||||||||
66 | L3.2 | 2000 | 1 | 1 | ||||||||||||
68 | L3.4 | 1000 | ||||||||||||||
Total CDi | 84,010 | 108,363 | 154,045 | 155,928 | 164,309 | |||||||||||
Total Cj | 14,950 | 14,900 | 14,850 | 15,000 | 14,950 | |||||||||||
Total z | 98,960 | 123,263 | 168,895 | 170,928 | 179,259 |
© 2020 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/).
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Sanchis, R.; Duran-Heras, A.; Poler, R. Optimising the Preparedness Capacity of Enterprise Resilience Using Mathematical Programming. Mathematics 2020, 8, 1596. https://doi.org/10.3390/math8091596
Sanchis R, Duran-Heras A, Poler R. Optimising the Preparedness Capacity of Enterprise Resilience Using Mathematical Programming. Mathematics. 2020; 8(9):1596. https://doi.org/10.3390/math8091596
Chicago/Turabian StyleSanchis, Raquel, Alfonso Duran-Heras, and Raul Poler. 2020. "Optimising the Preparedness Capacity of Enterprise Resilience Using Mathematical Programming" Mathematics 8, no. 9: 1596. https://doi.org/10.3390/math8091596
APA StyleSanchis, R., Duran-Heras, A., & Poler, R. (2020). Optimising the Preparedness Capacity of Enterprise Resilience Using Mathematical Programming. Mathematics, 8(9), 1596. https://doi.org/10.3390/math8091596