The rapid growth of digital business culture has created promising business development opportunities for companies to effectively and efficiently introduce new products and services (Guo et al., 2022). Many organisations are now turning to digital marketing to facilitate customer acquisition and establish a positive image both publicly and within business networks. Unlike traditional marketing, B2B digital marketing offers interactive online platforms that enable business marketers to accurately identify prospective customers, enhance information flow and foster trust in the business ecosystem (Krishna & Singh, 2018; Pandey & Gudipudi, 2019). Moreover, there is a distinction between B2B and B2C digital marketing at the strategic level. Most companies participating in B2B transactions are knowledgeable, tech-savvy and have solid business acumen (Lilien, 2016). B2B digital marketing focuses on value chain creation, professional content delivery, lead segmentation and customer engagement.

Conversely, B2C digital marketing focuses on brand building and end-consumer activities (Järvinen & Taiminen, 2016; Kannan & Li, 2017). In the digital age, strategies for achieving effective B2B digital marketing include business website development, search engine optimisation, online-to-office integration, social media promotion, pay-per-click campaigns and demographic targeting. The COVID-19 pandemic has accelerated the e-business transformation of B2B-centric organisations, with digital marketing adding value in this context.

Effectively leveraging social media and digital tools to promote a business to other companies is particularly crucial for driving sales (Fraccastoro et al., 2021). In recent years, KOLs have been discussed at length in the context of social media, with the term broadly referring to influencers who shape the decision-making processes and behaviours of a targeted group of customers (Lin et al., 2018). Influencers generally demonstrate high credibility, trustworthiness and professional expertise in their industry (Flodgren et al., 2019). According to Xue et al. (2023), KOLs in B2C digital markets strongly influence customer purchasing behaviours. However, research on KOLs in B2B digital marketing is still nascent (Crisafulli & Singh, 2022; Hudders et al., 2021). According to Mero et al. (2023), over 50 % of B2B companies lack the knowledge and ability to incorporate influencers into their business, as B2C strategies do not directly translate to the B2B context. This finding highlights a gap in understanding B2B digital marketing, particularly in selecting KOLs who can most effectively influence target customers and drive novel business competition.

In digital marketing, selecting the appropriate KOLs to promote a company's products and services is crucial. According to Oueslati et al. (2020), the KOL-identification process is complex, requiring a seven-phase framework: (i) understanding the domain, (ii) specifying available features, (iii) collecting data, (iv) constructing social networks, (v) modelling data, (vi) identifying KOLs and (vii) evaluating their performance. Effective KOL identification methods can employ six different approaches: descriptive, statistical and stochastic, diffusion process–based, topological, data mining and machine learning, and hybrid content mining (Bamakan et al., 2019). Cho et al. (2012) adopted a diffusion process–based approach, considering both diffusion speed and the increasing number of consumers who trust recommended purchasing decisions. Zhang et al. (2020) employed data mining to divide user leadership into user influence and activeness and design an action chain for opinion leaders. Park and Kaye (2017) proposed a hybrid content mining approach to examine Twitter content, aiming to identify connections between opinion leaders regarding network size and civil engagement.

Pozzi et al. (2016) outlined the major challenges surrounding KOL identification for B2B-centric organisations, which include identifying intrinsic and extrinsic characteristics and evaluating their market effectiveness and influence. This underscores the importance of considering multidimensional factors such as user activities, the follower–following network structure and the flow of influential power. Conducting an in-depth study that quantifies multiple criteria becomes essential for systematically identifying, evaluating and ranking KOLs for specific business organisations (Lin et al., 2016; Zhou et al., 2018).

MCDA approaches have been extensively developed to aid multi-criteria decision-making processes. These include service assessment (Langemeyer et al., 2018), portfolio evaluation (Pasaoglu et al., 2018) and the ranking of global market regions (Haddad et al., 2020). Four widely recognised methods of achieving multi-criteria decision-making have garnered significant attention from scholars: AHP, BWM, preference ranking organisation method for enrichment evaluations II, and elimination and choice expressing reality III. The selection of MCDA methods depends on problem features such as the nature of the alternative set, type of input set, nature of information, type of preference mode and type of decision. The decision process is also influenced by method features such as alternative ordering, criteria measure scale, preference structure, software availability and ease of use. While MCDA methods can robustly evaluate a set of alternatives using pairwise comparisons, they are less effective at intuitively capturing user preferences and understanding human thinking. The MCIA methodology – a composite of the MCDA, AI and fuzzy theories – is better equipped to handle imprecise knowledge in uncertain circumstances, making it suitable and practical for human-machine interactions (Frini, 2017). Fuzzy set theory can be embedded in existing MCDA methods to capture human intuition when making pairwise comparisons, with human expression modelled through fuzzy membership functions. For example, Sassi et al. (2015) applied MCIA to predict competitor decisions in complex business environments. The fuzzy BWM has also attracted increased attention due to its proficiency in pairwise comparisons and its ability to maintain consistency between judgements (Dong et al., 2021). This technique aims to capture the subjective judgements of decision-makers by using linguistic terms to specify the relative importance of criteria using fuzzy numbers (Amiri et al., 2021). In addition, the hybridisation of different decision analysis methods, such as AHP and TOPSIS (Bait et al., 2021; Bianchini, 2018; Leung et al., 2021), can effectively weight decision criteria to obtain a final ranking of alternatives.

Further improvements in these techniques, such as fuzzy TOPSIS, have incorporated multi-criteria decision-making (Nădăban et al., 2016; Nazim et al., 2022; Salih et al., 2019). Fuzzy TOPSIS was developed to evaluate multiple criteria of alternatives and rank them based on their similarity to an ideal solution, aiding the decision-maker in selecting the alternative that aligns most closely with their objectives (Solangi et al., 2021). Compared to typical MCDA methods, the MCIA approach provides a more robust mechanism for evaluating human intuition, which can be integrated with decision analysis methods. Therefore, they represent the ‘new era’ of multi-criteria decision-making.

KOL selection is a significant research focus in digital business management due to its value in sustaining business growth and development, particularly in the current digitalised environment. Professionals well-versed in digital markets can extend their impact beyond physical sales and marketing activities, significantly influencing other stakeholders and supporting the development of holistic digital business solutions. Currently, KOL selection relies heavily on human knowledge and experience, resulting in subjective decisions that can lead to inappropriate KOL selection. The scarcity of literature identifying potential KOL selection criteria in the digital B2B market exacerbates this issue. Without the support of a comprehensive decision-making system, selecting the most suitable KOL can be complicated, difficult and discouraging for businesses. To address this research gap, this study expands the scope of the MCIA methodology to encompass the selection and assessment of KOLs in the digital B2B context. This contribution aims to enhance sales and build trust within business networks.

In the first phase, in-depth consultations with managers across various companies were conducted to identify the existing challenges in digital business management and solicit opinions concerning selecting suitable KOLs. One common concern highlighted by these discussions was the importance of selecting KOLs with relevant knowledge and experience in advertising and selling B2B products and services as a company representative. This is a key consideration, as the experience of some KOLs is limited to B2C advertising and sales. In response to the identified problems, specific knowledge goals were defined to facilitate decision-making in the KOL selection process. These data were then stored in the cloud database to design the iMcKAF.

To simplify pairwise comparisons when ranking potential KOLs, fuzzy BWM was integrated with fuzzy TOPSIS. Specifically, the weights of core and sub-criteria were assessed using fuzzy BWM, and KOLs were ranked and assessed using optimised weights and fuzzy TOPSIS. This allowed for the development of an efficient method of ranking a set of potential KOLs with fewer pairwise comparisons. Fig. 2 shows the three-tiered iMcKAF architecture.

Fig. 2.

The three-tiered iMcKAF framework.

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In Phase 3, a case study was conducted to evaluate and validate the iMcKAF model, with the case study company implementing the proposed model to support KOL selection. Subsequently, performance evaluation and validation were conducted for the iMcKAF to compare the reliability and consistency of fuzzy BWM with another traditional MCDA approach.

Before deploying the MCIA methodology, a hierarchical structure for KOL selection and evaluation was developed. The essential elements for building the hierarchical structure were established by reviewing B2B digital marketing, theories concerning opinion and market leaders and KOL performance measurements. To comprehensively evaluate the knowledge, skills and experience of potential KOLs, five criteria and 19 sub-criteria for assessing KOLs in the context of B2B digital marketing were defined (Table 2). Additionally, an industry investigation was conducted to identify potential KOLs by studying existing B2B business models and the availability of KOLs in the market. The MCIA methodology, combining fuzzy BWM and fuzzy TOPSIS, can be implemented as a practical and intelligent approach to ranking and selecting appropriate KOLs for B2B companies.

As the criteria are identified, each criterion is assigned a different weight based on relevance and importance. In Tier 2, a set of adjusted weights and vectors for criteria and sub-criteria is listed in the hierarchical structure. Weighting is determined via the fuzzy BWM, specifically through pairwise comparisons conducted with targeted business customers based on formulated linguistic terms. This facilitates the subsequent quantification of market preferences regarding the criteria employed in selecting KOLs.

According to the hierarchical structure shown in Table 2, the pairwise comparisons at levels 1 and 2 were conducted for criteria K and sub-criteria SK, where K = {K1, K2, …, Kn}, SK = {SK1, SK2, …, SKn}, SKi = {Ki1,…,Kini} and i = 1, 2, …, n. The comparisons amongst criteria or sub-criteria were formulated using the triangular fuzzy number Fi = {li, mi, ui}, where li, mi and ui denote the lower bound, midpoint and upper bounds of the linguistic term i for the triangular fuzzy numbers. According to Wang (2021), fuzzy triangular numbers can more accurately handle complex and multi-criteria decision problems. For example, the linguistic term ‘equally important’ is represented by the triangular fuzzy number (0, 1, 2). Table 3 shows the fuzziness transformation between linguistic terms and the triangular fuzzy numbers used in the fuzzy BWM, which includes graded mean integration representation (GMIR) and consistency index (CI) for the triangular fuzzy number. The GMIR refers to the graded λ-preference integration representation, where λ = 1/2, as Eq. (1) shows, and the CI is used to measure the consistency ratio (CR) of the pairwise comparison to ensure measurement consistency.

The pairwise comparisons at levels 1 and 2 consider two scenarios representing differences between (i) the five major criteria and (ii) the 19 sub-criteria. For every pairwise comparison, the best (most influential) and worst (least influential) criteria (i.e. Kb and Kw for major criteria and SKib and SKiw for sub-criteria) were identified. In contrast, the best-to-others and others-to-worst pairwise comparisons were conducted using defined linguistic terms, as shown in Fig. 3. Two evaluation vectors were subsequently formulated to perform (2n−3) comparisons between criteria or sub-criteria, where n is the number of criteria or sub-criteria. A nonlinear optimisation problem was formulated to determine the adjusted weights of criteria and sub-criteria. First, it was necessary to minimise the absolute gap ξ in the differences between ωb/ωi and the triangular fuzzy number of the best criterion Kb, and between ωi/ωw and the triangular fuzzy number of the worst criterion Kw. The values ωi, ωb and ωw denote the fuzzy weights for criterion i, the best criterion and the worst criterion. The corresponding objective function for minimising ξ is formulated in Eq. (2). The constraints for this minimisation problem are as follows: (i) constraint (3) assesses the absolute gap between the ωb/ωi and the triangular fuzzy number of the best criterion Kb, which is less than ξ; (ii) constraint (4) determines the absolute gap between ωi/ωw and the triangular fuzzy number of the worst criterion Kw, which is also less than ξ; (iii) constraint (5) stipulates that the sum of GMIR values for the fuzzy weights of all criteria is equal to 1; (iv) constraint (6) ensures that the sequence of triangular fuzzy number (l, m, u) is maintained; (v) constraint (7) ensures the non-negative integrality of the lower bounds of triangular fuzzy numbers and ξ.

Fig. 3.

Best-to-others and others-to-worst pairwise comparisons.

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Subject to:

When using fuzzy BWM, the CR can be measured to determine the consistency of the results. For example, a small CR value (i.e. ≤ 0.1) is preferred. The CR is calculated by dividing the obtained optimal ξ* value by the CI, where the CI is the maximum possible ξ value in a pairwise comparison. CI values between 0 and 1 can be determined by solving a quadratic equation at the highest level of a linguistic term used in the pairwise comparison, as shown in Eq. (8), where u0 denotes the largest of the upper bound fuzzy numbers of the linguistic terms used in a pairwise comparison.

The output of the above approach determines the optimal value of ξ and the fuzzy weights of the major criteria and sub-criteria in the hierarchical structure. This enables the derivation of the sets of adjusted weights for criteria and sub-criteria. The notations used in the fuzzy BWM model are summarised in Table 4.

Fuzzy TOPSIS (rather than the fuzzy BWM) was employed to determine the suitability of the KOLs for the designated business customers. This reduced the complexity associated with ranking a large group of KOLs based on the major criteria and sub-criteria. As with the fuzzy BWM, a conversion table between linguistic terms and triangular fuzzy numbers was required for fuzzy TOPSIS (Table 5).

In the fuzzy TOPSIS process, decision-makers at B2B digital marketing service providers evaluate a set of KOLs using the 19 level-2 sub-criteria to formulate the fuzzy decision matrix. Table 6 presents the notations used for fuzzy TOPSIS. The identified sub-criteria were then classified as benefit or cost characteristics. This refers to whether they are favourable or unfavourable in terms of the goal of the MCIA, namely, KOL selection in the B2B market of interest. Next, the normalised fuzzy decision matrix {npq} can be established, as in Eq. (9), where p and q represent the sets of KOL alternatives and sub-criteria. This is then multiplied by the fuzzy weights of the sub-criteria obtained via fuzzy BWM to establish the weighted normalised fuzzy decision matrix, as in Eq. (10).

Subsequently, the fuzzy positive ideal solution (PIS) and fuzzy negative ideal solution (NIS) can be computed, as in Eq. (11). This enables two vectors, E+ and E−, to be obtained as a collection of fuzzy PISs and fuzzy NISs for all sub-criteria.

The distance matrices for (i) E+ and each alternative and (ii) E− and each alternative can also be measured, allowing evaluation of the distances d+ and d− by summing the distances between all sub-criteria, as in Eq. (12), where d(vps,vs+/−)=13[(lpsk−lsk+/−)2+(mpsk−msk+/−)2+(upsk−usk+/−)2]. Thus, vectors d+and d− can be determined for all KOL alternatives.

Finally, the closeness coefficient CCi can be computed using Eq. (13) for the set of potential alternative KOLs. According to the derived CCi value, the decision-maker can rank potential KOLs for designated business customers. This enables the decision-maker to select the most appropriate KOL to promote the company's products and services and establish trust with target customers.

Digital marketing is more complex for B2B than for B2C businesses. D.M. Digital Marketing Company Limited (an alias, hereafter D.M.), the B2B digital marketing agency under investigation in this case study, is a renowned digital marketing agency headquartered in Hong Kong, offering customised integrated digital marketing, social media marketing, creative marketing campaigns and influencer marketing solutions. According to D.M., B2B digital marketing demands professionalism and clarity. The company aims to establish a professional and trustworthy image amongst its intended business clientele, fostering collaboration and encouraging transactions. Regarding business growth, companies exclusively focused on B2B services and transactions prioritise profitability.

Moreover, effective B2B digital marketing strategies should motivate and persuade entire stakeholder groups and target customers to consider increasing marketing campaign budgets. Marketing agencies traditionally identify KOLs for specific business networks through professional associations, business exhibitions, conferences and face-to-face meetings. In the wake of the COVID-19 pandemic and its impact on global technological development, KOL identification has expanded to business-orientated social media (e.g. LinkedIn). While D.M. has adopted effective measures for identifying KOLs, recommending the most appropriate KOL to maximise benefits in the B2B market remains challenging. Within the B2B sector, establishing a systematic method for ranking potential KOLs and selecting the most appropriate one can effectively foster business collaborations between KOLs and companies, thereby enhancing synergy across business networks.

The criteria and sub-criteria for KOL selection (Table 2) were integrated into the analytical process for implementing the iMcKAF at the case study company. Subsequently, KOL selection can be incorporated as a service available on B2B digital marketing platforms. The overall implementation process requires four core steps: (i) collecting data from the B2B company, (ii) determining the adjusted weights for criteria and sub-criteria, (iii) collecting data from the decision-maker and (iv) ranking potential KOLs and selecting a suitable KOL.

Building on the various MCDA methodologies, the proposed framework creates a hybrid of fuzzy BWM and fuzzy TOPSIS to achieve systematic functionality in KOL selection. Traditionally, integrating fuzzy AHP and fuzzy TOPSIS has garnered significant attention in solving multi-criteria selection problems. This MCDA approach proves promising, easy to apply, adaptable and effective in facilitating the selection process in business environments and addressing various industrial challenges (Agrawal et al., 2019; Bait et al., 2021; Leung et al., 2021; Sirisawat & Kiatcharoenpol, 2018). However, fuzzy AHP has several drawbacks, including its unsuitability for pairwise comparisons and difficulty maintaining measurement consistency (Guo & Zhao, 2017). When fuzzy AHP is replaced with fuzzy BWM, pairwise comparisons decrease from n(n − 1)/2 to 2n−3, improving the ease of using the MCIA methodology and enhancing measurement reliability and consistency. The case study also involved a comparative analysis of CRs between fuzzy AHP and fuzzy BWM (Fig. 4) that revealed that the reliability and consistency of the pairwise comparison using fuzzy BWM outperforms the pairwise comparison using fuzzy AHP. Therefore, the integration of fuzzy BWM and fuzzy TOPSIS warrants further investigation as an alternative to fuzzy AHP.

Fig. 4.

Comparison of CRs when using the fuzzy BWM versus the fuzzy AHP.

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The proposed framework empowers marketing agencies to recommend KOLs who are best suited to B2B companies based on their domain expertise, digital marketing experience, personal characteristics, message distribution channel and customer engagement. The case study results indicate that the proposed framework can effectively resolve existing challenges in KOL selection while systematically collecting and evaluating the perspectives and needs of both the B2B company and decision-makers at the marketing agency. Building on existing approaches to KOL identification in business networks, this study analysed the challenge of identifying KOLs in the B2B context, considering multidimensional factors. Rather than simply applying multi-criteria decision-making approaches, an element of AI (i.e. data fuzziness) was embedded to develop the MCIA approach. This approach strengthened the methodology's capacity to understand linguistic expressions by businesspeople and decision-makers, embedding intelligence in decision aid for KOL selection. This study has developed intelligent platforms that allow B2B digital marketing agencies to provide comprehensive solutions for business promotion, brand building and opportunity exploration by facilitating the selection of the right KOL to act as the company's public representative (Fig. 5). Combined with existing KOL identification mechanisms and digital transformations, such as robotic process automation, intelligent agents can be designed and developed to effectively and consistently contribute to decision-making processes in alignment with prominent initiatives of the digital age.

Fig. 5.

Overview of intelligent KOL selection by a B2B digital marketing agency.

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This study synthesised the hierarchical structure of KOL selection via an extensive investigation of the recent literature, leading to the selection of five core criteria and 19 corresponding sub-criteria to contribute to a critical decision-making process in B2B digital marketing: KOL ranking and selection. A novel integration of the fuzzy BWM with fuzzy TOPSIS was proposed as an MCIA methodology to achieve this goal. This approach offers advantages, including simplifying pairwise comparisons, assessing data fuzziness, and improving measurement consistency. This integration can be extended to other B2B digital marketing domains that must consider multidimensional criteria, such as marketing strategy selection, market evaluation and performance measurement. Most prominently, this study has explored intelligent solutions for KOL selection, a critical step in B2B digital marketing for ranking KOLs and identifying the most suitable KOL to represent specific companies. This systematic approach generates ranking and selection results with high levels of consistency and reliability. A business philosophy involving appropriate market influencers can enable a company to effectively communicate with targeted customer segments and establish a circle of trust to induce synergistic business collaboration.