Abstract
The authors develop a three-stage framework for strategic marketing planning, incorporating multiple artificial intelligence (AI) benefits: mechanical AI for automating repetitive marketing functions and activities, thinking AI for processing data to arrive at decisions, and feeling AI for analyzing interactions and human emotions. This framework lays out the ways that AI can be used for marketing research, strategy (segmentation, targeting, and positioning, STP), and actions. At the marketing research stage, mechanical AI can be used for data collection, thinking AI for market analysis, and feeling AI for customer understanding. At the marketing strategy (STP) stage, mechanical AI can be used for segmentation (segment recognition), thinking AI for targeting (segment recommendation), and feeling AI for positioning (segment resonance). At the marketing action stage, mechanical AI can be used for standardization, thinking AI for personalization, and feeling AI for relationalization. We apply this framework to various areas of marketing, organized by marketing 4Ps/4Cs, to illustrate the strategic use of AI.
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Artificial intelligence (AI) in marketing is currently gaining importance, due to increasing computing power, lower computing costs, the availability of big data, and the advance of machine learning algorithms and models. We see wide applications of AI in various areas of marketing. For example, Amazon.com’s Prime Air uses drones to automate shipping and delivery. Domino’s pizza is experimenting with autonomous cars and delivery robots to deliver pizza to the customer’s door. RedBalloon uses Albert’s AI marketing platform to discover and reach new customers. Macy’s On Call uses natural language processing to provide an in-store personal assistant to customers. Lexus uses IBM Watson to write its TV commercial scripts, “Driven by Intuition.” Affectiva, based on affective analytics, recognizes consumers’ emotions while they are watching commercials. Replika, a machine learning-based chatbot, provides emotional comfort to consumers by mimicking their styles of communication. It has even been asserted that AI will change the future of marketing substantially (Davenport et al. 2020; Rust 2020). However, academic marketing research to date provides insufficient guidance about how best to leverage the benefits of AI for marketing impact.
The academic literature on AI in marketing may be sorted into four main types. These are (1) technical AI algorithms for solving specific marketing problems (e.g., Chung et al. 2009; Chung et al. 2016; Dzyabura and Hauser 2011, 2019), (2) customers’ psychological reactions to AI (e.g., Luo et al. 2019; Mende et al. 2019), (3) effects of AI on jobs and society (e.g., Autor and Dorn 2013; Frey and Osborne 2017; Huang and Rust 2018), and (4) managerial and strategic issues related to AI (e.g., Fountaine et al. 2019; Huang and Rust 2020).
The fourth literature stream, managerial issues related to AI, is currently dominated by consultants gravitating to the latest hot topic, and largely lacks a solid academic basis, albeit there are some recent studies trying to tackle strategic marketing issues. Examples include unstructured data for various areas of marketing (Balducci and Marinova 2018), analytics for consumer value in healthcare (Agarwal et al. 2020), machine learning prediction for mobile marketing personalization (Tong et al. 2020), in-store technology (e.g., robots, smart displays, or augmented reality) for convenience or social presence (Grewal et al. 2020), and AI for personalized customer engagement (Kumar et al. 2019).
To facilitate the strategic use of AI in marketing, we develop a three-stage framework, from marketing research, to marketing strategy (segmentation, targeting, and positioning, STP), to marketing actions (4Ps/4Cs), for strategic marketing planning incorporating AI. This strategic AI framework is based on a more nuanced perspective of the technical development of AI, existing studies on AI and marketing, and current and future AI applications. It can be used for strategic marketing planning, for organizing the existing AI marketing studies, and for identifying research gaps in AI marketing.
This paper contributes to the strategic application of AI in marketing by developing a framework that guides the strategic planning of AI in marketing in a systematic and actionable manner. It is achieved by bringing together diverse AI literatures on algorithms (e.g., Bauer and Jannach 2018; Davis and Marcus 2015), psychology (e.g., Lee et al. 2018; Leung et al. 2018), societal effects (e.g., Autor and Dorn 2013; Frey and Osborne 2017), and managerial implications (e.g., Huang et al. 2019) to explore what those literatures can tell us about managing AI in marketing. Marketing is an applied field, and using the more foundational literatures to inform marketing practice is an important role for marketing academia. This paper also contributes to strategic marketing research by providing a systematic and rigorous approach to identifying research gaps that bridge strategic AI marketing practice and research.
Conceptual foundation
The marketing research–strategy–action cycle
We propose a three-stage strategic planning framework based on the marketing research–marketing strategy–marketing action cycle. Similar cycles have been proposed, such as Deming’s (1986) plan-do-check-act cycle, but that cycle omits the role of strategy. Our cycle views strategic planning as a circular process, starting from conducting marketing research to understand the market, the firm, the competitors, and the customers; to developing strategies for segmentation, targeting, and positioning; and to designing specific marketing actions to execute the strategy. This cycle does not stop at marketing actions. The execution of marketing actions will feed back to marketing research as market data, which constitutes a continuous cycle for marketing research–strategy–action, as illustrated in Fig. 1.
Multiple AI intelligences
Figure 1 illustrates that AI can play critical roles in all three strategic marketing stages. It shows that there are multiple AI intelligences that a marketer can leverage: mechanical, thinking, and feeling.
We conceptualize AI as the use of computational machinery to emulate capabilities inherent in humans, such as doing physical or mechanical tasks, thinking, and feeling; the multiple AI intelligence view considers that, rather than treating AI as a thinking machine, AI can be designed to have multiple intelligences, as humans have, for different tasks. Ordered by the difficulty with which AI can address them, there are mechanical, thinking, and feeling AI intelligences (Huang and Rust 2018; Huang et al. 2019).
Mechanical AI is designed for automating repetitive and routine tasks. For example, remote sensing, machine translation, classification algorithms, clustering algorithms, and dimensionality reduction are some current technologies that can be considered mechanical AI.
Thinking AI is designed for processing data to arrive at new conclusions or decisions. The data are typically unstructured. Thinking AI is good at recognizing patterns and regularities in data, for example, text mining, speech recognition, and facial recognition. Machine learning, neural networks, and deep learning (neural networks with additional layers) are some of the current methods by which thinking AI processes data. IBM Watson, expert systems, and recommender systems are some current applications for decision making.
Feeling AI is designed for two-way interactions involving humans, and/or for analyzing human feelings and emotions. Some current technologies include sentiment analysis, natural language processing (NLP), text-to-speech technology, recurrent neural networks (RNN), chatbots for mimicking human speech, embodied and embedded virtual agents for human interactions, and robots with customized hardware for sensing affective signals (McDuff and Czerwinski 2018).
It is important to note two qualifications of this multiple AI intelligences view. First, although we set up three intelligences, the assignment of some applications to a particular intelligence is mainly based on the purpose they are used for. Sometimes those applications may have some elements of more than one intelligence; thus, suggesting that the three intelligences are fuzzy sets (Varki et al. 2000). For example, facial recognition that is trying to identify someone is thinking AI (e.g., customs uses it to identify potential terrorists), while facial recognition that is trying to figure out somebody’s emotional state from their facial expression is feeling AI (e.g., advertisers use it to identify audience responses to ads). Second, we do not have true feeling AI yetFootnote 1; thus, the current practice is to use thinking AI to analyze emotional data (e.g., affective analytics) and two-way interactions (e.g., chatbots and social bots). Emotional data are distinct from cognitive data, in that they are contextual, individual-specific, and typically multimodal (speech, gestures, and language). Such data are about the individual in context, meaning that feeling AI needs to incorporate contextual and individual-specific data into modeling the emotional state of an individual.
Multiple benefits of AI
Each of the AI intelligences can deliver its unique benefit: mechanical AI is best for standardization, thinking AI is good for personalization, and feeling AI is ideal for relationalization (Huang and Rust 2020).
Mechanical AI provides standardization benefits due to its ability to be consistent. In marketing, various forms of mechanical AI have been used to provide a standardization benefit; for example, collaborative robots (cobots) help with packaging (Colgate et al. 1996), drones distribute physical goods, self-service robots deliver service, and service robots automate social presence in frontline (Mende et al. 2019; van Doorn et al. 2017). All these applications aim to generate standardized, consistent, and reliable outcomes.
Thinking AI provides personalization benefits, due to its ability to recognize patterns from data (e.g., text mining, speech recognition, facial recognition). Any marketing functions and activities that can benefit from personalized outcomes should consider thinking AI. The most common applications in marketing are various personalized recommendation systems (Chung et al. 2009; Chung et al. 2016), such as Netflix movie recommendations and Amazon cross-selling recommendations.
Feeling AI provides relationalization benefits (i.e., personalizes relationships), due to its capability to recognize and respond to emotions. Any marketing functions or activities that require interaction and communication, with the goal of relational benefits (e.g., when customer lifetime value is high) should consider feeling AI—one example being customer service. A broad range of marketing functions involves feelings, for example, customer satisfaction, customer complaints, customer moods, and emotions in advertising, etc., and can make use of feeling AI.
The strategic AI framework
We propose a three-stage strategic framework for using AI in marketing that leverages the three AI intelligences and their benefits, as shown in Fig. 1. At the marketing research stage, AI is used for market intelligence, including mechanical AI for data collection, thinking AI for market analysis, and feeling AI for customer understanding.
At the marketing strategy stage, AI is used for the strategic decisions of segmentation, targeting, and positioning. Specifically, mechanical AI is ideal for discovering novel customer preference patterns in unstructured data, thinking AI is ideal for recommending the best segment(s) to target, and feeling AI is ideal for communicating with the targeted customers about the product.Footnote 2
At the marketing action stage, AI is used for the benefits of standardization, personalization, and relationalization, individually or synergistically. Marketers need to decide which AI intelligence(s) to use for which marketing actions. For example, payment and delivery are functions that can benefit from standardization by using mechanical AI, such as automatic payment and delivery tracking. Digital marketing can benefit from personalization by using thinking AI, such as various recommendation systems. Customer service and frontline customer interaction can benefit from relationalization by using feeling AI, such as social robots greeting customers and conversational AI providing customer service. The discussion of the strategic use of AI in marketing action is organized in terms of the marketing 4Ps/4Cs, to balance both the marketer and customer sides. Table 1 defines various strategic elements of this strategic AI framework, Table 2 illustrates marketing actions by using mechanical AI for standardization, thinking AI for personalization, and feeling AI for relationalization, with various examples and current and future scenarios,Footnote 3 and Table 3 summarizes the existing literature for using AI in each of the strategic elements. We discuss this three-stage framework in the following sections.
Marketing research
At this strategic stage, mechanical AI can be used for data collection, thinking AI for market analysis, and feeling AI for customer understanding.
Mechanical AI for data collection
Mechanical AI can automate data collection about the market, the environment, the firm, the competitors, and the customers. In the digitally connected world, market data can be easily tracked and monitored. Data sensing, tracking, and collection are routine, repetitive tasks that can be easily automated by mechanical AI.
Existing studies have shown various ways of using mechanical AI for data collection. For example, customer intelligence, including data about consumers, their activities, and their environments, can be collected if they use connected devices (Cooke and Zubcsek 2017), product usage and consumption experience can be visualized with Internet of Things (IoT) (Ng and Wakenshaw 2017), various advanced technologies and analytics can capture unstructured marketing activity data (Balducci and Marinova 2018), in-car sensors can track driving behavior for determining insurance premiums (Soleymanian et al. 2019), and retail technologies, such as heat maps, video surveillance, and beacons, can be used for profiling and recognizing retail shoppers (Kirkpatrick 2020). These studies show that, given the repetitive, routine, but high-volume nature of market data, mechanical AI can collect data efficiently at scale.
The data collection capability of mechanical AI is not limited to observable behavioral data; it can also be used to facilitate survey or experimental data collection to capture consumer psychographics, opinions, and attitudes. For example, human administration and supervision of ongoing surveys are no longer required and can be automated. SurveyMonkey and SurveyCake are two commercial survey platforms that automate survey design and data collection.
Thinking AI for market analysis
Thinking AI can be used to identify competitors in a well-defined market or outside options in a new market, and to derive insights for a product’s competitive advantages (i.e., the way the product can do better than competitors to meet customer demands). For example, supervised machine learning can be used for a mature market where the market structure is stable and known to marketers, whereas unsupervised machine learning can be used for a new market or spotting outside options where the market structure and trends are unstable and unknown to marketers.
In marketing practice, predictive analytics are commonly used to predict volatile market trends and customers’ heterogeneous preferences. For example, Gap, the fashion clothing brand, uses it to predict fast fashion trends to better meet customer needs, and Amazon uses it to predict a customer’s future orders (i.e., anticipatory fulfilling).
Existing studies have demonstrated various potential uses of thinking AI for market analysis. Automated text analysis can be applied for consumer research (Humphreys and Wang 2018), for marketing insights (i.e., prediction and understanding) (Berger et al. 2019), and for analyzing consumer consideration heuristics (Dzyabura and Hauser 2011). Machine learning algorithms and lexicon-based text classification can be used to analyze various social media datasets (Hartmann et al. 2019). Also, big data marketing analytics is now a mainstream approach for generating marketing insights (Berger et al. 2019; Chintagunta et al. 2016; Liu et al. 2016; Wedel and Kannan 2016).
Specific applications include mapping market structures for large retail assortments using a neural network language model, by analyzing the co-occurrences of products in shopping baskets (Gabel et al. 2019), detecting copycat mobile apps using a machine learning copycat-detection method (Wang et al. 2018), and aiding social media content engineering by employing natural language processing algorithms that discover the associations between social media marketing content and user engagement (Lee et al. 2018).
Feeling AI for customer understanding
Feeling AI can be used to understand existing and potential customer needs and wants, for example, who they are, what they want, and what their current solutions are. The major distinction between market analysis and customer understanding is that the latter often involves emotional data about customer sentiments, feelings, preferences, and attitudes. Thus, feeling AI can do a better job of understanding customers than mechanical AI and thinking AI, due to its capability of analyzing emotional data.
For existing customers, marketers can use feeling AI to answer the questions of whether they are happy with the product and why. Existing customers’ preferences are more stable, and a company has past and current transaction data for a deeper understanding. For example, Affectiva partnered with Ford to create AutoEmotive sentiment analysis, to try to figure out drivers’ emotional states.
For potential customers, marketers can use feeling AI to understand what they want and why they are happy with competitors or outside options. Potential customers’ needs and wants are more difficult to predict, and their emotional data are less available. In marketing practice, Albert AI, Adgorithm’s AI-driven marketing platform, has been used by RedBalloon to discover and reach new customers (Sutton 2018) and by Harley-Davidson to identify high potential customers based on the company’s customer relationship management database, personalizing the marketing campaign accordingly (Power 2017).
In academic research, existing studies have shown various approaches of using feeling AI to understand customers. For example, the sentiment expressed by consumers in social media (e.g., online reviews, tweets), including explicit and implicit language and discourse patterns, can be analyzed to understand consumer responses using their own language (Hewett et al. 2016; Humphreys and Wang 2018; Ordenes et al. 2017), the interaction between conversational AI and customers can be enhanced by applying analytical mapping to script appropriate response sequences that make customers feel that they have a “conversation” with AI (Avery and Steenburgh 2018), consumer consideration heuristics can be understood by machine learning (Dzyabura and Hauser 2011), and customer needs can be identified from user-generated content using convolutional neural network machine learning (Timoshenko and Hauser 2019).
Marketing strategy (STP)
At this strategic stage, marketers can use AI for the three key strategic decisions: segmentation, targeting, and positioning. However, before proceeding to specific STP decisions, marketers need to decide the overall strategic positioning to guide their STP decisions. Huang and Rust (2017) propose a technology-driven approach to positioning a firm’s strategy along the dimensions of standardization–personalization and transaction–relationship. A firm can pursue a commodity strategy that uses automated/robotic technology for efficiency, a relational strategy that cultivates the existing customers’ lifetime value, a static personalization strategy that uses cross-sectional big data analytics (e.g., like-minded customers) for personalization, or an adaptive personalization strategy that uses longitudinal customer data for dynamic personalization over time. This strategic positioning will guide firms’ STP decisions. For example, if a firm pursues the static personalization strategy, the firm may want to have a big, relevant, existing and potential customer database and let unsupervised machine learning explore patterns of preference or purchase behavior as the basis of targeting and positioning. If a firm pursues the adaptive personalization strategy, the firm may want to use supervised machine learning to continue analyzing existing customers’ satisfactions/dissatisfactions over time (which may not be big). However, if firms embrace a data-driven approach to STP, it can rely more heavily on AI to explore the STP possibilities.
In general, this stage of strategic decisions relies more on thinking AI, for its capability of processing data to arrive at new conclusions or decisions. However, it is worth reiterating that the assignment of some applications to a particular intelligence is mainly based on the purpose an application is used for. For example, when thinking AI becomes completely routinized, as is often the case in segmentation applications, it shares many of the characteristics of mechanical AI, because it simply identifies patterns from data routinely and repetitively, without involving much about the purpose of making new decisions (e.g., segmentation but not retargeting).
Segmentation
Segmentation is to slice a market into pieces, with customers in each piece having unique needs and wants, for example, using gender to slice the shoe market into male and female shoes segments; and using price and quality to slice the air travel market into budget and premium airlines segments. Mechanical AI, especially the various mining and grouping techniques, has the strength of identifying novel patterns from data.
AI segmentation is flexible, in that it can disaggregate the market into segments of one (i.e., each individual customer is a segment) and can aggregate scattered long tails into one segment. Wang et al. (2017) demonstrate that transfer learning can be used to model the tail of the distribution, by learning from the head of the distribution and transferring the learning to the data-poor tail. This flexibility in aggregation and disaggregation allows marketers to find the right size of segment.
Existing studies have shown how data mining can be used to uncover patterns that are difficult for human marketers to see. For example, text-mining and machine learning can be used to automatically process and analyze loan requests to slice borrowers into good customers (those will pay back the loan) and bad customers (those will not) (Netzer et al. 2019), automated text analysis and correspondence analysis can be used for psychographic consumer segmentation in the art market (Pitt et al. 2020), data mining can be used to obtain tourist segments based on the meaning of destinations to consumers, that is better than the classic clustering methods (Valls et al. 2018), and retail customers can be micro-segmented based on their preferences for personalized recommendation (Dekimpe 2020).
Targeting
Targeting is choosing the right segment(s) on which to focus the firm’s marketing actions. Slicing the market is more mechanical and can be done automatically by mechanical AI, given the relevant data. However, choosing the right segment requires domain knowledge, judgement, and intuition. Various technologies and analytics have been used for targeting, such as search engines using keywords searched and browsing history to target search consumers, and social media platforms using interests, content, and connections to target social media consumers (Liu 2020). The representative AI for this decision is recommendation engines that can recommend various potential targets for marketing managers’ final verdict, and predictive modeling that can be used to choose which segment to target.
Existing studies show that various thinking AI can be used for this purpose. Examples include targeting customers using a combination of statistical and data-mining techniques (Drew et al. 2001), screening and targeting cancer outreach marketing using machine learning and causal forests (Chen et al. 2020), optimizing promotion targeting for new customers using various machine learning methods (Simester et al. 2020), identifying the best targets for proactive churn programs from field experimental data using machine learning techniques (Ascarza 2018), and profiling digital consumers for targeting using online browsing data (Neumann et al. 2019).
Positioning
Positioning bridges product attributes and customer benefits by finding a competitively advantageous position for the product in customers’ minds. This term is often associated with brand positioning or advertising positioning for its association with customer perceptions and communications to maintain a desirable perception. Daabes and Kharbat (2017) demonstrate how data mining techniques can be used to distill a customer-based perceptual map, as an alternative to marketer knowledge, from mining customers’ perceptions.
Compared with the mechanical-based segmentation and the thinking-based targeting, positioning is more about speaking to customers’ hearts, typically as a positioning statement or slogan in promotional communication. Gali et al. (2017) find that tourism positioning slogans in top destinations tend to emphasize the affective component.
Some successful positioning statements help brands to occupy a unique position in customers’ minds and thus succeed in the market for a long time. For example, Nike’s “Just do it,” Apple computer’s “Be different,” and McDonalds’ “I’m loving it” all communicate with customers by speaking to their hearts. Feeling AI, such as feeling analytics, is ideal for this strategic decision to help develop compelling slogans by understanding what resonates with target customers.
Academic research on this decision is sparse, indicating a research gap for using feeling AI to create compelling positioning.
Marketing action
At this strategic stage, marketers can use mechanical AI for standardization, thinking AI for personalization, and feeling AI for relationalization (Huang and Rust 2020). Depending on which benefit is desirable, a marketer can use multiple AI intelligences individually or collectively. We illustrate the use of AI intelligences in various areas of marketing with examples and current and future scenarios, and support the illustration using the existing literature. The discussion is organized by marketing 4Ps (product, price, place, and promotion) (Kotler and Keller 2006) and the corresponding 4Cs (consumer, cost, convenience, and communication) (Lauterborn 1990) to emphasize that the 4P actions need to be able to deliver consumer benefits.
Product (consumer)
Product (consmer) actions include goods and services as offerings to meet the consumer’s needs and wants. Such actions typically include product design, packaging, branding, and returns, and the associated customer services in these activities. We illustrate this decision using product/branding and customer service, with product/branding representing the “product” side and customer service representing the “consumer” side. Product and branding are related in that branding is the identity (e.g., name, symbol, logo) of a product. We put them together to maintain the simplicity of the table.
Product/branding focuses on product creation (including tangible goods R&D and production, and service innovation and process) and branding (i.e., the identity of a product).
Mechanical AI can be used for product/branding actions that can benefit from standardization. For example, brand logo design can be automated by a decision-tree like machine learning using multiple-choice questions, allowing small budget marketers to have AI-assisted branding (Avery 2018). Product adoption and acceptance can be tracked and monitored automatically. While enjoying the standardization benefit of mechanical AI, one existing study is cautious about automating product decisions, when those products are related to consumers’ identity (Leung et al. 2018).
Thinking AI can be used for product/branding actions that can benefit from personalization. For example, marketing analytics can predict market trends for product design that cater more precisely to target customers’ preferences, big data analytics can be used to inform product development to quickly adapt to consumer trends and changing preferences (Dekimpe 2020), topic modeling can advance service innovation and design (Antons and Breidbach 2018), adaptive systems can be used to personalize service to each consumer’s preference (Chung et al. 2009; Chung et al. 2016; Dzyabura and Hauser 2019; Liebman et al. 2019), and deep learning can be used to personalize point-of-interest recommendations (Guo et al. 2018).
Feeling AI can be used for product/branding actions that can benefit from relationalization. For example, conversational AI can be trained to have brand personality to interact with customers (Wilson and Daugherty 2018), machine learning can recommend TV programs based on the viewer’s mood, brands can track their reputation through text and sentiment analyses tweets, reviews, and social media posts (Rust et al. 2020), and chatbots can mimic customers’ communication style to provide emotional support. Kumar et al. (2019) provide a systematic exploration about the role of AI in personalized engagement marketing, an approach to create, communicate, and deliver personalized offering to customers. Huang and Rust (2020) show that feeling AI can be used to engage customers in service interaction.
From the consumer side, existing studies further show that customers have varying responses and attitudes toward using AI products. For example, consumers may be resistant to personal medical AI (Longoni et al. 2019), identity-based consumption automation (Leung et al. 2018), and anthropomorphized consumer robots (Kim et al. 2019; Mende et al. 2019). These studies put a boundary condition for marketers when using AI in the product/branding actions to generate positive customer responses.
Customer service is emotionally charged, yet is also costly. A marketer can handle customer service using the three AI intelligences to balance the cost/satisfaction tradeoff in serving customers.
Mechanical AI, such as text-based chatbots, is widely used online to handle a massive amount of routine customer service. Most customer questions can be answered by such bots. As long as such automation is not related to customers’ identity (Leung et al. 2018), it is easy to implement, cost-efficient, and scales up easily.
Thinking AI, such as natural language processing chatbots, can handle more diversified customers and idiosyncratic issues (e.g., multicultural customers with accents and contextual-dependent complaints). This is an AI version of the old telephone menu, except that customers are talking to chatbots, rather than human customer service agents. Although a recent study shows that customers may not feel comfortable yet about talking to chatbots (Luo et al. 2019), with the wider acceptance of AI and the further advance of chatbots, we can expect the acceptance to increase over time.
Feeling AI, such as Cogito’s emotional AI systems, can analyze the pace of speaking, energy and empathy, and common errors of conversations, and gives in-call guidance to customer service agents in call centers that make the conversations more natural and engaging.
Price (cost)
Price (cost) action includes the tasks of payment, price setting, and price negotiation, which is the cost that the consumer pays for the product.
The payment task is routine and can be handled best by mechanical AI. Apple Pay, Google Pay, PayPal, Amazon Payments, and Square are some popular automatic payment methods for online marketers.
The price setting task is calculation-intensive and analytical, which is the strength of thinking AI. Misra et al. (2019) demonstrate that multiarmed bandit algorithms from statistical machine learning can dynamically adjust online prices in real-time, even if price information is incomplete. Bauer and Jannach (2018) show that a machine-learning framework based on Bayesian inference can optimize online pricing even when data are updated frequently, and are sparse and noisy. Prices can also be personalized by incorporating consumer online WOM (Feng et al. 2019) and consumers’ private personal information (Montes et al. 2019). Dekimpe (2020) proposes that retailers can use big data to optimize dynamic best-response pricing algorithms that consider consumer choices, competitor actions, and supply parameters.
The price negotiation task is interactive; thus, feeling AI is in a better position to undertake this task. Pulles and Hartman (2017) hypothesize that interpersonal likeability would impact the price negotiation outcome in a B2B relationship, suggesting that interaction, communication, and sentiment may be critical for price negotiation.
Place (convenience)
Place (convenience) is the way that the consumer can access the product. We discuss two broad categories of place action: Retailing and frontline, virtually or physically, in which interactions play a key role; and distribution, logistics, and delivery, in which convenience is the key.
Retailing/frontline is the area of marketing that most employs embodied AI (i.e., robots) to facilitate frontline interactions.
Mechanical AI can be used to automate backend marketing processes and frontend interactions. In the backend, service processes can be automated (Huang and Rust 2018) and retail processes can be optimized using IoT (Grewal et al. 2018). In the frontend, service robots can interact with scale and consistency (Wirtz et al. 2018), and can automate social presence in the frontline (Mende et al. 2019; van Doorn et al. 2017). Frontline service robots are common; for example, Giant grocery uses the robot Marty to identify hazards in store (e.g., detecting milk spilled on the floor) and HaiDiLao hotpot uses robots to deliver soup base from kitchen to table side. Grocery shopping is typically repeat purchase, which does not involve too much interaction, communication, and emotion, and thus using mechanical AI to automate the marketing function is desirable.
At the thinking level, due to the direct customer contact nature of retailing, AI is used to facilitate in-store shopping for individual customers. Amazon Go, an experimental grocery store, uses facial recognition technology to identify and remember each customer, Macy’s On Call, a mobile shopping personal aid, provides in-store information to help customers locate items they are looking for, and Alibaba’s FashionAI system uses smart mirrors in sales floor and changing rooms to display items that each customer selects and suggests complementary items.
Feeling AI can be used to enhance interaction and engagement. For example, service robots can easily do surface acting (Wirtz et al. 2018), and “one-voice” AI can enhance customer engagement by integrating various interfaces involved in a customer’s journey (Singh et al. 2020). At the feeling level, various embodied robots are used to engage customers and optimize their experience. For example, Pepper robots are used by Marriott to greet and interact with customers. Hotels and travel typically involve more interactions and more emotions, and thus feeling AI naturally suits. Nevertheless, marketers need to be cautious, in that anthropomorphized robots are found to increase perceived warmth but decrease liking (Kim et al. 2019); thus, in the case of embodied frontline robots, marketers need to take the appearance of robots into consideration.
Distribution/logistics/delivery is an area of marketing in which many functions and processes can be highly automated; including packaging, inventory, warehousing, supply chain, logistics, and delivery, to provide convenience benefits to customers.
Tasks in distribution are mostly mechanical, routine, and repetitive; thus, the standardization benefit of mechanical AI fits well. We have seen cobots for packaging, drones for delivery, IoT for consumption tracking and order refilling, and self-service technologies for delivering service to customers directly. Such standardization provides a convenience benefit to customers.
Moving up to the thinking AI level, we have seen that a customer’s future orders and refills can be anticipated by predictive analytics, and ordered products can be delivered to customers using autonomous cars equipped with facial recognition technology (e.g., JD.com and Domino’s use self-driving cars for delivery).
So far, feeling AI is not as widely used as the other two AI intelligences for this marketing action, due to distribution’s mechanical and thinking nature.
Promotion (communication)
Promotion (communication) is the marketing communications between the consumer and the marketer. It can include personal selling, traditional mass media advertising, and more commonly nowadays direct marketing, database marketing, and digital marketing (social media marketing, mobile marketing, search engine optimization, etc.). All these can benefit from AI intelligences.
Mechanical AI is ideal for automating various repetitive, routine, and data intensive functions of promotion (Huang and Rust 2018). Most of these are about promotional media planning and executions. Examples include automating advertising media planning, scheduling, and buying; automating search campaigns execution, keywords researching, and bidding; automating social media targeting, retargeting, and posting. Especially considering the real-time nature of digital marketing, such automation greatly aids marketers’ efforts in the labor-intensive, high-time-pressure process.
Thinking AI has great potential for promotion content creation and personalization. For example, AI content writers can facilitate the generation of ad or post content. A recent example was a Lexus car commercial that used IBM Watson to create the “Driven by Intuition” commercial script. Content can be personalized and optimized to different customer profiles at different locations and different times. Kantar Analytics uses content analytics to help advertisers create content that shortens the idea-to-value time and maximizes content effectiveness (Gopinath 2019).
Feeling AI can be used to track real-time customer response to promotional messages (like, dislike, disgusted, funny, etc.) and then adjust what to deliver and what to emphasize in both media and content. At the feeling level, more real-time and accurate emotion sensing from posted messages can better engage customers and provide a better interaction experience (Hartmann et al. 2019; Lee et al. 2018).
Managerial implications
Our framework provides a roadmap for marketers to implement various AI intelligences in marketing, strategically and systematically. Table 4 summarizes the managerial implications of the framework by contrasting current marketing practice with the emerging AI-enabled marketing practice. The two practices should be viewed as two ends of a continuum, with more AI intelligences expected to be used for more strategic elements at the three stages over time. We discuss these implications below.
Implications for marketing research
At this stage, marketers need to decide (1) how to use AI to identify competitors (including competitors in the same industry and outside options) and to understand competitive advantages (i.e., the way the product can do better to meet customers’ needs), and (2) how to use AI to discover and understand existing and potential customers (i.e., who they are, what they want, and what their current solutions are) and to understand their preferences and feelings. For firms that embrace a theory-driven approach to marketing strategies, data and intelligences resulting from this stage play a critical role.
Data collection
Currently, surveys, experiments, interviews, panels, and sales data are still the major approaches for marketers to obtain data, even though the administration of these methods can be partially automated or facilitated by technology. Surveys and experimental methods tend to be more theory driven, while other methods tend to be more data driven. Marketers often also rely on thirty-party syndicated data (e.g., YouGov), especially for external data that are difficult for the firm to collect. These data are typically delayed, out of context, and ad hoc, meaning that they are collected periodically, after the fact (after consumption has occurred), and not during data generation.
By contrast, emerging practices automate most of the data collection by connecting technology (e.g., IoT, social networking sites, mobile apps), sensor technology (e.g., remote sensing, detection), and wearable technology (e.g., smart watch, Fitbit). These mechanical AI approaches track and capture real-time data when they are occurring. Thus, the data are in context, about the customer, and during the consumption experience. Such spontaneous data collection tends to be more data driven, but if theories can be developed priori to guide and update the continuous data collection, they can be theory driven as well.
Market analysis
Current market analysis, although marching toward machine learning-based analysis rapidly, still relies heavily on statistical analysis to analyze structured data for marketing insights. It is also common for firms to purchase third-party data and analysis, especially for external market and competitor analysis. Such analysis tends to be standardized across firms (with limited degree of customization), and thus the insights derived from it are less useful for deriving a unique value proposition. Firms also monitor and analyze first-party data, especially for firm marketing resource analysis and for existing customer analysis for which internal data are available.
By contrast, big data and machine learning-based analytics are the emerging approach for marketing insights. Online reviews, opinions, and behaviors all can be mined, and data can be in text, image, audio, or video. When the question at hand is clear (e.g., a mature brand), supervised machine learning can be used to conduct theory-driven analysis, whereas when the question at hand is unclear (e.g., a new brand), unsupervised machine learning can be applied to obtain data-driven insights. Balducci and Marinova (2018) offer a detailed description of various methods of analyzing unstructured data in marketing. More advanced approaches to marketing analysis include using deep learning methods such as predictive analytics, computational creativity, personalization algorithms, and natural language processing systems, to come up with intuitive suggestions for marketing strategies.
Customer understanding
Current practice relies heavily on focus groups to gain qualitative insights about customers. Focus groups are time consuming and labor intensive, not to mention not representative. Marketers also observe customers’ behaviors and choices, and their reactions to promotions to understand their preferences and the underlying reasons.
By contrast, data about customers’ feelings, moods, and emotions can be obtained directly from customers’ interaction with AI (e.g., conversational bots), rather than inferred from psychometrics, using conversational bots and analyzed using feeling analytics (e.g., posts on social media, voice recordings of customer interactions, and chat transcripts). Feeling analytics can identify customer insights with scale and cost-efficiently. Given that emotional data are personal and in context, understanding customers in context provides richer insights about who they are and what they like.
Implications for marketing strategy (STP)
At this stage, marketers can leverage the three AI intelligences for segmentation, targeting, and positioning, respectively. For firms that embrace a data-driven approach to marketing strategy, this stage may play a bigger role than conclusions derived from marketing research.
Segmentation
The current approach relies on the marketer’s intuition and domain knowledge to choose a limited number of segmentation variables with which to slice the market, such as demographics, psychographics, and behavioral variables. Such an approach sees customers as aggregate, not individual. For example, some customer equity models focus on segmenting customers based on their acquisition and churn rates, and do not see them as individually unique (e.g., Blattberg and Deighton 1996; Gupta et al. 2004). Artificial personas thus are often applied to these segments to help marketers make the aggregate segments more personal and relatable.
By contrast, when data mining is used to segment the market, it no longer requires marketers to decide segmentation variables on an a priori basis, because unsupervised machine learning can discover the patterns itself. A virtually unlimited number of variables can be used to slice the market in a novel way that often goes beyond any pattern that human marketers can see. It is like the customer lifetime value model, in which each customer is valuable in some way. The Target store knowing a daughter is pregnant before her father knows, by mining the daughter’s purchase patterns, is a classic example.
Targeting
Currently targeting mostly uses marketers’ subjective judgment, based on the resources, the competitive advantage of the firm, and the value of the segment to the firm. It is typically at the segment level (not individual level), and often trades off segment size for effectiveness.
By contrast, after very refined segmentation, it is thinking AI’s turn to recommend the best segment(s) to target. It is very well likely to be a segment of one, since personalization is the strength of thinking AI. With the capability to slice the market in unlimited ways and at the individual customer level, targeting in emerging practice is more commonly at the individual customer level. For example, online ads use cookies to target individual customers by following them around, wherever they go on the Internet. The new targeting also is flexible, because it can aggregate individual customers into a segment, if they have similar preferences (e.g., like-minded customers recommendation, aggregating long-tail customers even when each individual customer may not be valuable), or it can disaggregate a segment, if heterogeneity within the segment becomes manifest. Targeting involves not just identifying segments but also determining whether they should be pursued. Whether they should be pursued or not is a matter of predicting the outcome if they pursue, and prediction at the individual level is only scalable with the help of AI.
Positioning
Positioning is currently a human task, for it involves judgment, intuition, and creativity that machines are not particularly good at it yet (Davis and Marcus 2015; Schoenick et al. 2017). Kelly (2019) argues that creativity is not just about novelty but is also about social acceptability. A novel idea has to be accepted by community to be deemed as creative. Because creativity is socially embedded, a good positioning is in the eye of the targeted customers. Although we have seen an increasing number of examples of AI participating in the creative process, for example using AI to compose its own music and to write short stories, there is still a long way to go for AI to be as creative as humans while still maintaining strategic relevance. For example, the script of the 2018 Lexus car “Driven by Intuition” TV commercial was created by AI by applying the machine learning approach. Lexus fed machines with award-winning luxury ads, Lexus brand data, and emotion data, that were shown to connect with viewers, to tell the story about how Lexus generated the new ES executive saloon car. The commercial appears to have face validity as a luxury car commercial. However, this commercial may not be very strategic because the ad has an unclear customer segmentation and ambiguous positioning (Rust and Huang 2020). This real-world example illustrates that positioning can be expected to be a human-AI collaboration for the immediate future.
Implications for marketing action
At this stage, marketers can leverage the three AI intelligences for the 4Ps to serve the 4Cs. The key questions to answers are which AI to use and how to use it for marketing actions.
Product
The current practice for product decisions is to use conjoint analysis to decide what levels of product attributes to include in product development, use test markets to decide whether and to what degree the product will be accepted, and use aggregate sales results after the launch of the product as a proxy for customer feedback.
The emerging practice is to use mechanical AI to automate production and service process (e.g., Huang and Rust 2020), use thinking AI, such as cognitive technology, to facilitate product research and development (which is currently more common in drug development), and use feeling AI, such social robots and conversational bots, to interact with customers, from which they obtain real-time, first-hand customer feedback about the product. Such a process can become an adaptive loop that improves the product continuously based on customer feedback.
Price
The current practice is to list prices on retail stores, websites, or mobile apps, set the prices discriminately, based on segments, and have salespeople handle price negotiations. Price menus offline are difficult and labor intensive to change, and price menus online, though easier to update, are also easier to be compared. Price setting typically requires careful and extensive calculation, taking various factors into consideration. Price negotiation is more of an art than a science, especially for big ticket items.
The emerging practice is to use mechanical AI to automate price setting and changes, thinking AI for price personalization, and feeling AI for price negotiation. Price updating is a simple routine task, price setting can be achieved by the powerful calculating machine, thinking AI, and can be personalized taking individual customers’ preferences and sensitivity into consideration. Price negotiation can be done when feeling AI detects customer reactions to the offered price in real-time.
Place
The current practice relies on self-service to automate routine delivery and labor-intensive physical distribution for ordering processing, materials handling, and delivery; unskilled labor at the frontline to offer homogeneous assistance, and frontline employees for emotional labor.
Distribution, logistics, and delivery can mostly be automated with mechanical AI, and is a fast-growing emerging practice, for example, product tracking systems for firms to track where the product is in the supply chain, and for customers to track when they can expect to receive the product. Thinking AI, such as personal shopping assistants, has been used to assist customers about where to find the product. Feeling AI, such as conversational bots, can be used to display emotions in service interaction without the need to actually experience emotions (Wirtz et al. 2018).
Promotion
The media planning part of promotion has a higher degree of automation by mechanical AI, due to the repetitive nature of the task. The content creation part of promotion, though having a lower degree of automation, is increasingly handled by thinking AI, such as AI writers, to generate content on its own, or to stimulate human creativity. Customers’ reactions to promotion are still mostly measured using traditional marketing research methods. The emerging practice is to use feeling AI, such as feeling analytics, to sense, react, and adjust promotions in real-time based on customers’ emotional reactions.
Directions for future research
The framework lays out a stage-by-stage circular process for using different AI intelligences in marketing. It provides rich implications for future research based on the use of AI intelligences. We discuss these implications, organized by the three AI intelligences. The last column of Table 4 illustrates one example research question for each element.
Marketing research
When mechanical AI is used for data collection, it makes both the competition and the customer more transparent, making the governance of privacy issues more central to marketers. When thinking AI is used for market analysis, it turns theory-driven marketing research into data-driven, resulting in a debate about whether a data or theory approach to marketing research should be embraced. When feeling AI is used for customer understanding, it is as if AI can really understand emotions, when we don’t have true emotional machines yet. These issues give rise to various future research topics.
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How would privacy and data security affect marketing’s use of AI for data collection? When mechanical AI is used to collect and integrate multiple sources of real-time, in-context consumer data, the risk of privacy infringement and the consequences of a data breach are much higher. It is more difficult to keep such “all-in-one” data anonymous, and consumers are more sensitive to data sharing and data breaches. We have seen the public outcry when Facebook permitted the unauthorized licensing of 30 million user accounts to Cambridge Analytica, with its brand reputation plummeting dramatically in two weeks (Rust et al. 2020). In the AI age, both competition and customers become more transparent, due to AI’s data collection capability. How should privacy and data security be handled? The existing studies suggest that both data and consumer characteristics need to be considered. It has been shown that some types of data are more sensitive, such as personal data, financial data, health data, or medical records. Agarwal et al. (2020) urge healthcare organizations to find ways of protecting patient privacy as a competitive advantage, because healthcare consumers are especially weak in protecting their own data. It has also been shown that some consumers are more sensitive to data sharing. Thomaz et al. (2020) identify two types of consumers who vary in willingness to share information. They advise that marketers need to understand which type of consumers they are dealing with when providing personalization. Some methods of protecting marketing data have been proposed (Schneider et al. 2017, 2018). Future research will need to explore more delicate approaches to handle the ubiquitous data collected by AI.
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How to balance data- and theory-driven market analysis? Traditional market research has the strength of hypothesis testing, whereas the emerging machine learning approach to analyzing unstructured big data has the merit of data exploration. How to balance the two approaches of inquiry and benefit from them? The Silicon Valley viewpoint is that prediction, driven by data, is everything. Balducci and Marinova (2018) show a data-driven approach to marketing management and research and Ma and Sun (2020) argue for machine learning methods for marketing research, while Lehmann (2020) proposes a method to blend theory and data in the evolving world of marketing research. These practices and studies suggest that AI will expand the role of exploration in the development of theory; thus, investigating how the two approaches can be balanced, integrated, or blended would allow marketing to leverage the benefit of data-driven market analysis.
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What algorithms and models are needed for feeling AI? Much of the progress in technical algorithms has been made in the area of deep learning neural networks, applied to thinking AI problems, such as personalized advertising. The current neural network-based machine learning is mainly for prediction, rather than for understanding. We need algorithms to understand emotions and react to emotions appropriately (Rust and Huang 2020). There are different ways to understand emotions, such as understanding emotions in written language (text-based sentiment analysis), in oral conversation (natural language processing), or in facial expression (facial recognition). Although there is some work already in using thinking AI to analyze emotional data (e.g., affective analytics), with respect to facial recognition and natural language processing, models in this area are still fairly rudimentary.
Marketing strategy
For the three strategic elements of segmentation, targeting, and positioning, mechanical AI can slice the market based on virtually an unlimited number of variables, thinking AI can recommend the target, even if it is a segment of AI customers, or a combination of AI and human customers, and feeling AI can team up with marketers to come up with creative positioning that touches consumers’ hearts. We discuss these implications.
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How best to visualize segmentation? The emerging AI approach to segmentation can be based on an unlimited number of variables. This creates a challenge as to how best to visualize for marketers to make sense of these multi-dimensional segmentation results for targeting. Thinking AI can easily decipher such complexity, but human marketers may not. Earlier studies have attempted to visually display three-dimensional segmentation and positioning from a larger set of variables (e.g., Donthu and Rust 1989; Rust et al. 1992). There are some existing tools, but they are not designed for STP decisions. We need better and friendlier human-computer interfaces to summarize and display those extremely high dimensional results to inform human marketers.
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What happens when the customer is AI? Alexa and Siri are not the only AI that can potentially buy things. Increasingly, customers use AI as their agents for information collection, price negotiation, or purchase. When it becomes more real that marketers will be catering to non-human customers (Rust 1997, 2020) or a combination of humans and AI as customers, how AI customers would behave, and how marketers should serve them are both pertinent issues. Are customer emotions still pertinent? Will rational decision making become the only route to decisions? How will AI customers change the scope of consumer research?
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How should marketers and AI collaborate, to resonate with customers? Positioning requires creativity and empathy about the preferred way that a customer would like to see a product. AI can optimize a positioning recommendation, but may not be mature enough to resonate with customers, given that we do not have true feeling AI yet. Thus, for the time being, it is important to explore the best approaches to marketer-AI collaboration for a positioning that resonates with customers. This is a question that involves exploring the role of AI intelligences in creativity; for example, to what extent should marketers let machines be creative on their own (e.g., the Lexus commercial example), or use them as creative support? What will be consumers’ attitudes toward machine-generated creativity? What will decide the acceptance or rejection of machine creativity?
Marketing action
For the four strategic elements of 4Ps/4Cs, as illustrated in Table 4, all three AI intelligences can be applied to each element. We illustrate one research question for each of the elements, highlighting the level of AI intelligence that is likely to help the most.
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How is AI best used in developing new products to meet customer needs and wants? Thinking AI can be innovative and creative, but it may not be straightforward as to whether the new products will meet customer needs and wants, because many of those needs and wants are implicit, rather than explicit. This is the challenge of converting product attributes into consumer benefits. Rogers’ (1962) diffusion of innovation theory suggests that both consumer and product innovativeness matter for new product acceptance. AI, with its capability to find patterns and regularities in data that otherwise would be hard to see, can be used to uncover consumers’ implicit needs and wants, and match those needs and wants to products at different stages of lifecycle. For example, for the earlier stages of product lifecycle, AI may play a bigger role, because consumers’ needs and wants tend to be implicit, whereas for the latter stages, human marketers may play a bigger role, because those needs and wants become more explicit.
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How to manage AI-based price negotiation? Negotiating price to achieve price personalization can be expected to be more common and increasingly at the individual level (e.g., price bidding). The price discrimination literature (e.g., Montes et al. 2019) tends to view pricing as a process of marketers setting the price and consumers reacting to the price. In AI-based price negotiation, the process is dynamic and real-time. We have seen the popularity for technology giants to use AI for price negotiation, such as Google’s search keywords bidding and Facebook’s ad bidding for reaching the desirable customers. What will be the new mechanisms and methods for pricing when AI is used to negotiate prices more widely?
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How to manage customer disengagement due to place automation? The goal of the place decision is to provide the customer a convenience benefit. When the entire place process is automated, which is increasingly common these days, there is no human-to-human contact, and thus it is likely for customers to become less engaged with the brand. How to avoid customer disengagement while striving to provide convenience? Are there ways to mitigate the part that is lost?
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How to use AI to build strong relational bonds? When two-way communications and interactions are made easier and richer by AI, how are trust and commitment affected by interacting with AI? What will be gained, and what will be lost? Customers may have changed by interacting with AI. For example, when AI does more thinking, will customers think less when they may feel more? To what extent does the advance of AI, from mechanical, to thinking, to feeling, lead to customers feeling more, at the expense of thinking, such as accepting fake news on social media at face value?
Current limitations of AI
Our strategic framework illustrates applications of multiple AI intelligences to various areas of marketing at different strategic decision stages. These applications are not without limitations. We discuss the major limitations of applying the three AI intelligences to marketing for marketers to use AI more wisely.
Limitations of mechanical AI
Although current mechanical AI has the strong capability of collecting and integrating multiple sources of data autonomously, very often contexts of the data are lost, creating problems in modeling, especially for emotional data. The automated process of data collection also makes customer intimacy less achievable because it is machines talking to machines.
Non-contextual data
Many data collected by mechanical AI are non-contextual. This is especially the case for emotional data because such data are about the individual in context, meaning modeling the emotional state of a consumer requires contextual and individual-specific data. Contextual data are often lost during interaction. One Dell AI expert said at a frontline service conference in 2019 that it is not that difficult to model emotions (meaning using the existing machine learning approach), but the difficulty lies in that emotional data are difficult to capture, and thus are not analyzed. For example, in a customer service interaction, the content and sentiment of the conversations are recorded, but not the context of the conversations. When an angry and frustrated customer calls, his way of talking may be different, depending on whether he is alone or with a group of friends, whether the weather is gloomy or sunny, or whether the traffic is jammed or smooth. Even if voice analytics can detect the sentiment of his voice, it cannot provide guidance to the customer agent as to why the customer is angry, and what the best way to respond is (Rust and Huang 2020).
Machine to machine interactions
Or communications are predicted to be the key emerging technology-enabled interactions in digital environments (Yadav and Pavlou 2020). Examples include an ATM getting authorization from the bank for a cash withdrawal, and a refrigerator sensor sending inventory information to a vendor via IoT. Mechanical AI plays an important role in those routine interactions; however, it may come at the cost of customer intimacy (e.g., Treacy and Wiersma 1997). To be able to figure out the customer side of strategy requires customer data, collected and compiled by mechanical AI, which is the only methodology that is powerful enough and scalable enough to capture individual-level data. When customers are removed from the interactions, it is more challenging for marketers to remain intimate with customers. Machine-to-machine interactions and communications will be a new form of customer interactions that calls for more future studies to tell marketers how to approach them, and how to keep a balance between operational efficiency and customer intimacy.
Limitations of thinking AI
Current thinking AI, though powerful, may not be neutral and transparent, which can result in biased recommendations or entail unintended consequences.
Opaque AI
How thinking AI comes up with a certain recommendation often is not transparent to human marketers. The current dominant machine learning approach to AI designs machines to learn via a mapping mechanism (i.e., map input pairs (X,Y) to output Y=F(X)), not via cognitive reasoning (Lewis and Denning 2018). This results in the output being unexplainable because it does not answer the “why” question. Thus, there is a need for scholars to develop explainable AI so that thinking AI can be used for trustworthy and fair marketing exchanges (Rai 2020). Opaque AI also results in liability issues. If AI output is not transparent, when AI goes wrong, marketers who use the AI are likely to be held accountable. The accountability issue has emerged since the first fatal accident of an autonomous car. Thus, marketers, as AI users, when using thinking AI for strategic decisions, need to strive to use the most explainable AI, rather than just the most powerful AI, to keep the exchanges transparent to both the marketer and the customer.
AI biases
Thinking AI is not neutral. If data input is erroneous or biased, output is likely to be biased too. However, biased input is not the only way AI bias can occur. For example, it has been shown that for loan decisions, discriminatory results can occur even if there is no bigotry programmed into the system, and the system only seeks to maximize profit (Ukanwa and Rust 2020). Researchers have also shown that gender bias can occur without any conscious (or unconscious) attempt to produce a biased outcome—using only an unbiased algorithm (Lambrecht and Tucker 2019).
Marketing researchers have addressed some issues, such as managers and management education underpreparing the next generation for feeling and emotional intelligence (Huang and Rust 2018; Huang et al. 2019), and IoT may impose constraints and restrictions on consumer journeys (Hoffman and Novak 2018; Novak and Hoffman 2019). Thus, in using thinking AI for market analysis, for targeting, and for personalized marketing actions, marketers need to be aware of the potential AI biases and have better knowledge about how AI learns to avoid AI biases.
Limitations of feeling AI
Although using feeling AI for two-way interactions involving humans and for analyzing human feelings and emotions is common in marketing due to the high-touch nature of many marketing functions (e.g., frontline interactions, customer service, and emotional ad appeals), we don’t yet have true emotional machines that can recognize, act, and react to human emotions appropriately. The substitutive use of mechanical and thinking AI for feeling AI may generate some unintended consequences.
Technology unreadiness
The fact that marketers are using “lower” intelligence AI for feeling functions (i.e., using mechanical AI to capture emotional data and using thinking AI to analyze emotional data) may inflate the perceived capability of AI to assist marketers in understanding customer emotions. For example, marketers may overly rely on such feeing AI to interact with customers, resulting in customer disengagement. Srinivasan et al. (2016) find that higher levels of customer activity on social media lead to disengagement (i.e., Facebook unlikes). Unlikes, as affective responses, may imply that customer responses may be polarized more easily if technologies (social media in their study) are not able to interact with customers appropriately.
Customer unreadiness
Another consideration is that customers may not be ready for interacting with feeling AI. Luo et al. (2019) find that many customers hang up on call-out marketing chatbots once they realize they are talking to bots. The Technology Readiness Index surveyed what people think about AI in the workplace and only 10% consider feeling AI to have the biggest impact in the past 5 years on their jobs, indicating that customers are not aware that AI can “have” feelings and may constitute a threat to their jobs (Espino 2019).
Contributions and conclusions
The most disruptive aspect of AI is that it replaces and improves upon human thinking capability. One of the most revolutionary characteristics of modern thinking AI is its ability to personalize by analyzing big data in an automatic way. This creates a quantum leap in marketing’s ability to target individual customers. Marketing primarily requires thinking intelligence and feeling intelligence. Until now there has been only limited ability of technology to help with those things. Now as thinking AI is advancing rapidly, it is gaining the ability to assume many of the thinking tasks in marketing. Eventually will even assume many of the feeling tasks in marketing, as AI develops further. Such efforts are already underway by researchers.
We see that marketers who cannot wait for technology to sufficiently advance use mechanical AI and thinking AI for feeling tasks, due to true feeling AI not being ready yet. We also see that AI intelligences may not be used in the most effective way (e.g., collecting customer data indiscriminately or accepting AI recommendation blindly). Thus, we develop this strategic framework to help marketers leverage the benefits of multiple AI intelligences for marketing impact. In this framework, we lay out the ways in which various AI intelligences can be used in marketing research, marketing strategy (STP), and marketing action (4Ps/4Cs). It shows the strategic roles that AI can play in marketing, as well as points out the limitations of current AI, to help marketers use AI wisely.
Notes
According to Huang and Rust (2018), true feeling AI needs to be able to recognize, emulate, and respond appropriately to human emotions.
The term “product” is used to refer to both tangible goods and intangible services.
The two strategic stages, marketing research and marketing strategy, are less relevant for this marketing practice illustration.
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Funding
This research was supported by grants (106-2410-H-002-056-MY3 and 107–2410-H-002-115-MY3) from the Ministry of Science and Technology, Taiwan.
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Huang, MH., Rust, R.T. A strategic framework for artificial intelligence in marketing. J. of the Acad. Mark. Sci. 49, 30–50 (2021). https://doi.org/10.1007/s11747-020-00749-9
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DOI: https://doi.org/10.1007/s11747-020-00749-9