Abstract
The present study identifies, organizes, and structures the available scientific knowledge on the recent use and the prospects of Voice Assistants (VA) in private households. The systematic review of the 207 articles from the Computer, Social, and Business and Management research domains combines bibliometric with qualitative content analysis. The study contributes to earlier research by consolidating the as yet dispersed insights from scholarly research, and by conceptualizing linkages between research domains around common themes. We find that, despite advances in the technological development of VA, research largely lacks cross-fertilization between findings from the Social and Business and Management Sciences. This is needed for developing and monetizing meaningful VA use cases and solutions that match the needs of private households. Few articles show that future research is well-advised to make interdisciplinary efforts to create a common understanding from complementary findings—e.g., what necessary social, legal, functional, and technological extensions could integrate social, behavioral, and business aspects with technological development. We identify future VA-based business opportunities and propose integrated future research avenues for aligning the different disciplines’ scholarly efforts.
Similar content being viewed by others
Introduction
Scholarly research across disciplines agrees that technological advancement is one of the important drivers of economic development because it brings about efficiency gains for all players of an economic system (Grossman and Helpman, 1991; Kortum, 1997; Dercole et al., 2008). Digitization and emerging technologies thus usually draw intense scholarly interest and are studied with the hope that their adoption will enable companies to generate “new capabilities, new products, and new markets” (Bhat, 2005, p. 457) based on new business models, specifically designed for digitalized life spheres (Chao et al., 2007; Sestino et al., 2020; Antonopoulou and Begkos, 2020).
One of the recent emergent digital technologies promising companies substantial future revenues from innovative user services is voice assistants (VAs). They are “speech-driven interaction systems” (Ammari et al., 2019, p. 3) that offer new interaction modalities (Rzepka et al., 2022).
Partly based on the integration of complementary Artificial Intelligence (AI) technology, they allow users’ speech to be processed, interpreted, and responded to in a meaningful way. In private households, we witness a rapid adoption rate of VAs in the form of smart speakers such as Amazon Echo, Apple Homepod, and Google Home (Pridmore and Mols, 2020) which, particularly in combination with customization of IoT home systems, provide a higher level of control over the smart home experience compared to a traditional setting (Papagiannidis and Davlembayeva, 2022). Available in the United States (US) since 2014 and in Europe since September 2016 (Trenholm, 2016; Hern, 2017), by 2018, already 15.4% of the US and 5.9% of the German population owned an Amazon Echo (Brandt, 2018). Overall, private household purchases already grew to 116% in the third quarter of 2018 compared to 2017 (Tung, 2018) and, according to a recent research report from the IoT analyst firm Berg Insight (Berg Insight, 2022), the number smart homes in Europe and North America reached 105 million in 2021. We realize that, at present, VAs represent an emergent technology that has its challenges (Clark et al., 2022), similar to the Internet of Things (IoT) or big data analytics technology. It has triggered an enormous amount of diverse scholarly research resulting “in a mass of disorganized knowledge” (Sestino et al., 2020, p. 1). For both scholars and managers, the sheer quantity of disorganized information is making it hard to predict the characteristics of future technology use cases that fit users’ needs or to use this information for strategy development processes (Brem et al., 2019; Antonopoulou and Begkos, 2020). While Computer Science scholars already debate the technological feasibility of specific and complex VA applications, Social Science research points to VA-related market acceptance risks resulting, for example, from biased choices offered by VA (Rabassa et al., 2022) or from not identifying and implementing the privacy protection measures required by younger people (Shin et al., 2018), motivated by frequent user privacy leaks (Fathalizadeh et al., 2022) and worries about adverse incidents (Shank et al., 2022). Recent studies also specifically emphasize the need to shift the focus to user-centric product value (Nguyen et al., 2022) in the pursuit of the most beneficial solutions in terms of social acceptance and legal requirements (Clemente et al., 2022). For the most beneficial solutions, a collaboration between companies or even industries is likely to be necessary (Struckell et al., 2021).
There are, to our best knowledge, no systematic review papers focusing on VAs from a single discipline’s perspective that we could draw from. We did find an exploration of recent papers about the use of virtual assistants in healthcare that highlights some critical points (e.g., VA limitations concerning the ability to maintain continuity over multiple conversations (Clemente et al., 2022) or a review focusing on different interactions modalities in the ear of 4.0 industry—highlighting the need for strong voice recognition algorithm and coded voice commands (Kumar and Lee, 2022). In sum, the research that might allow for strategizing around VA solutions that match the needs of private households is scattered and needs to be organized and made sense of from an interdisciplinary perspective to shed “light on current challenges and opportunities, with the hope of informing future research and practice.” (Sestino et al., 2020). This paper thus sets out to identify, organize, and structure the available scientific knowledge on the recent use and the prospects of VAs in private households and propose integrated future research avenues for aligning the different disciplines’ scholarly efforts and leading research on consistent, interdisciplinary informed paths. We use a systematic literature review approach that combines bibliometric and qualitative content analysis to gain an overview of the still dispersed insights from scholarly research in different disciplines and to conceptualize topical links and common themes. Research on emerging technologies acknowledges that the adoption of these technologies depends on more factors than just technological maturity. Also, social aspects (e.g., social norms) and economic maturity (e.g., can a product be produced and sold so that it is cost-effective) play an important role (Birgonul and Carrasco, 2021; Xi and Hamari, 2021). Research particularly emphasizes that emerging technologies need to not only be creatively and economically explored—but also grounded in the user’s perspectives (Grossman-Kahn and Rosensweig, 2012) and serve longer enduring needs (Patnaik and Becker, 1999). IDEO conceptualized these requirements into the three dimensions of feasibility, viability, and desirability (IDEO, 2009).
Feasibility covers all aspects of VA innovation management that assures that the solution will be technically feasible and scalable. This also includes insuring that legal and regulatory requirements are met (Brenner et al., 2021). The viability lens focuses on economic success. “Desirability” ensures that the solutions and services are accepted by the target groups and, more generally, desired by society (Brenner et al., 2021). While IDEO and their focus on innovation development processes relate to a different context, the main reasoning about the relevance of these three dimensions (technical, social, and management) is also applicable when looking for research literature that helps find strategies around VA solutions that correspond to people’s needs in private homes. To cover these three dimensions, we focus on studies from Computer Science (CS), Social Science (SS), and Business and Management Science (BMS) to advance our knowledge of the still dispersed insights from scholarly research and highlight shared topics and common themes.
With this conceptual approach, we contribute an in-depth analysis and systematic overview of interdisciplinary scholarly work that allows cross-fertilization between different disciplines’ findings. Based on our findings, we develop several propositions and a framework for future research in the interest of aligning the various scholarly efforts and leading research on consistent, interdisciplinarily informed paths. This will help realize VA’s potential in people’s everyday lives. We moreover identify potential future VA-based business opportunities.
This paper is structured as follows: the section “Business opportunities related to VA use in private households” summarizes the research on potential business opportunities related to the use of VAs in private households. The research methodology, i.e., our approach of combining a bibliometric literature analysis with qualitative content analysis in a literature review, is presented in the section “Methods”. Section “Thematic clusters in recent VA research” identifies nine thematic clusters in recent VA research, and section “Analysis and conceptualization of research streams” analyzes and conceptually integrates them into four interdisciplinary research streams. Section “Discussion: Propositions and a framework for future research, and related business opportunities” identify future business opportunities and proposes future directions for integrated research, and section “Conclusion” concludes with contributions that should help both scholars and managers use this research to predict the characteristics of future technology, use cases that fit users’ needs, and use this information for their strategy development processes around VA.
Business opportunities related to VA use in private households
Sestino et al. (2020, p. 7) argue that when new technologies emerge, “companies will need to assess the positives and negatives of adopting these technologies”. The positives of VA adoption lay mainly in the projection of large new consumer markets offering products and services where text-based human–computer interaction will be replaced by voice-activated input (Pridmore and Mols, 2020:1), checkout-free stores such as Amazon Go, and the use of VA (Batat, 2021). Marketing studies predict high adoption rates in private households due to potential efficiency gains from managing household systems and devices by voice commands anytime from anywhere (Celebre et al., 2015; Chan and Shum, 2018; Jabbar et al., 2019; Vishwakarma et al., 2019), as well as the high potential of health check app for improving communication with patients (Abdel-Basset et al., 2021) or realize self-care solutions (Clemente et al., 2022). A study by Microsoft and Bing (Olson and Kemery, 2019) substantiates that claim for smart homes by revealing that, already today, 54% of the 5000 responding US users use their smart speakers to manage their homes, especially for controlling lighting and thermostats. In surveys, users state that they envision a future in which they will increasingly use voice commands to control household appliances from the microwave to the bathtub or from curtains to toilet controls (Kunath et al., 2019). CS scholars discuss how to design complementary Internet of Things (IoT) technology features and systems to bring about such benefits (Hamill, 2006; Druga et al., 2017; Pradhan et al., 2018; Gnewuch et al., 2018; Tsiourti et al., 2018a/b; Azmandian et al., 2019; Lee et al., 2019; Pyae and Scifleet, 2019; Sanders and Martin-Hammond, 2019). BMS research additionally debates how companies should proceed to capture, organize, and analyze the (big) user data that become potentially available once VA is commonly used in private households, and to identify new business opportunities (Krotov, 2017; Sestino et al., 2020) and future VA applications, such as communication and monitoring services in pandemics (Abdel-Basset et al. 2021).
However, many recent studies also mention the negatives of VA usage, like worrying trends emerging from the so-called surveillance economy (Zuboff, 2019) or, instead, debate future questions, such as what happens when technology fails or what the rights of fully automated technological beings would be (Harwood and Eaves, 2020). 2050 out of the 5000 respondents to the Microsoft and Bing study reported concerns related to voice-enabled technology, especially about data security (52%) and passive listening (41%). The “significant new production of situated and sensitive data” (Pridmore and Mols, 2020, p. 1) in private environments and the unclear legal situation related to the usage of these data seem to act as one of the inhibitors to the adoption of more complex VA applications by users. Thus, many of the imaginable future use cases, such as advanced smart home controls (Lopatovska and Oropeza, 2018; Lopatovska et al., 2019) or personal virtual shopping assistance (Omale, 2020; Sestino et al., 2020), are still a long way off. Although technologically feasible and partly already available, today’s users use VAs for simple tasks, such as “searching for a quick fact, playing music, looking for directions, getting the news and weather” (Olson and Kemery, 2019). Therefore, companies are warned against too high expectations of fast returns. Moreover, there are also some technical issues, and only the not-yet-mature integration of further AI-enabled services in VA is expected to be a game changer leading to growth in the deployment of voice-based solutions (Gartner, 2019; Columbus, 2020).
At a meta-level, BMS research advises companies to explore and implement new technologies in their products, services, or business processes, because that might result in a considerable competitive first-mover advantage (Drucker, 1988; Porter, 1990; Carayannis and Turner, 2006; Hofmann and Orr, 2005; Bhat, 2005). At the same time, Macdonald and Jinliang (1994) have shown that in industrial gestation (or the impact of science on society), the evolution in the demand for technology, and a set of competitors go hand in hand. Consequently, the adoption of an emergent technology by “the ultimate affected customer base” (Bhat, 2005, p. 462) becomes of utmost importance when looking at how company investments pay off (Pridmore and Mols, 2020). This is particularly the case for VAs where companies are greatly dependent on the adoption of respective hardware—typically the aforementioned smart speakers (Herring and Roy, 2007)—or of new services, such as the envisioned digital assistants (Sestino et al., 2020, p. 7), by private users. VAs differ from other emergent technologies that allow companies to reap the benefits by implementing them in their own organization and reorganizing business or production processes, like RFID technology (Chao et al., 2007), nanotechnology (Bhat, 2005) or IoT-based business process (re)engineering (Sestino et al., 2020). Hence—although it is one of the most prominent emerging technologies discussed in current mass media—this might be one of the reasons for why there is yet very limited BMS research studying VA-related challenges and opportunities that could inform companies.
High-tech companies striving to develop VA-related business models need to consider and integrate scholarly knowledge from disciplines as different as CS, SS, and BMS to meet the requirements of “a secure conversational landscape where users feel safe” (Olson and Kemery, 2019, p. 24). However, such interdisciplinary perspectives are yet hardly available—instead, we see a large amount of scattered disciplinary scholarly knowledge. This situation makes it difficult to assess opportunities for future VA-related services and to develop sustainable business models that offer a potential competitive advantage. In this paper, we set out to contribute to such an assessment by organizing and making sense of the scholarly knowledge from CS, SS, and BMS. We follow earlier research on the assumption that assessing the state of emergent technologies and making sense of available knowledge on new phenomena requires an interdisciplinary perspective (Bhat, 2005; Melkers and Xiao, 2010; Sestino et al., 2020) to pin down and forecast the technology’s future impact and to advise companies in their technology adoption decisions (Leahey et al., 2017; Demidova, 2018; McLean and Osei-Frimpong, 2019). The literature review we present here is therefore additionally aimed at substantiating the call for interdisciplinarity of research into emerging technologies that aim to offer insights about business opportunities.
Methods
Our aim of making sense of a large amount of disorganized scholarly knowledge on VAs, assessing challenges and opportunities for businesses, and identifying avenues for future interdisciplinary research, made a systematic literature review appear to be the most appropriate research strategy: Literature reviews enable systematic in-depth analyses about the theoretical advancement of an area (Callahan, 2014). Earlier research with similar aims that studied other emerging technologies found the method “useful for making sense of the noise” (Sestino et al., 2020:1) in a fast-growing body of scholarly literature (Fig. 1).
For our research, we decided to combine a conventional literature review that applies qualitative content analysis, with bibliometric analysis. The bibliometric analysis provides an overview of connections between research articles and the intersection of different research areas (Singh et al., 2020). The qualitative content analysis-based literature review offers a more in-depth overview of the current state of the literature (Petticrew and Roberts, 2006). Earlier scholarly work indicates that such a combination is particularly useful for analyzing the current state of technology trends and the significance of forecasts (Chao et al., 2007; Li et al., 2019). Figure 2 depicts the methodological research approach of this study.
In the following, we describe the methodological approach in detail.
Article identification and screening
The literature search employed the Scopus database, as the coverage for the Scopus and Web of Science databases is similar (Harzing and Alakangas, 2016). In the literature search, we employed the keywords “voice assistant” and synonyms of it (“Voice assistant” OR “Virtual assistant” OR “intelligent personal assistant” OR “voice-activated personal assistant” OR “conversational agent” OR “SIRI” OR “Alexa” OR “Google Assistant” OR “Bixby” OR “Smart Loudspeaker” OR “Echo” OR “Smart Speaker”) and “home” and synonyms of it (“home” OR “house” OR “household”). The automated bibliometric analysis scanned titles, abstracts, and keywords of the article for these terms. We used the search field “theme” including title, abstract, and keywords (compare 3.2). Due to the focus of the research, the search was restricted to articles published in the CS, SS, and BMS areas, written in English, and published before May 2020.
We adopted the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) guide proposed by Moher et al. (2009) for the bibliometric literature review. The initial search yielded 428 articles in the CS, 356 articles in the SS, and 40 articles in BMS. After scanning the abstracts of all documents in the list of each field, further articles were excluded based on their relevance to our topic. The most frequent reason for excluding an article was that it was not about VAs—e.g., articles found with the keyword “echo” referred to acoustic phenomena. Table 1 displays the descriptive results of the bibliometric literature review.
The final dataset included 267 articles in CS, 52 articles in SS, and 20 articles in BMS.
Tables 2 and 3 display the most frequent countries of origin for SS and CS.
Tables 2 and 3 present the top countries of origin of the articles from CS and SS. There was no information related to the countries of origin of the bms articles. In view of the many (regionally differing) legal questions and regulatory issues, it is important to see that, while the US is leading the list by a large margin, the discussion is also spread over countries from different continents.
Data analysis step 1: Bibliometric literature review
The final dataset consisted of bibliometric information including the author names, affiliations, titles, abstracts, publication dates, and citation information. The bibliometric analysis was conducted in each discipline separately using the VOSviewer software. For each discipline, we visualized common knowledge patterns through co-occurrence networks in the VA literature. A co-occurrence network contains keywords with similar meanings that can distort the analyses. Therefore, synonyms were grouped into topics using the VOSviewer thesaurus to ensure a rigorous analysis. For example, the keywords „voice assistant“, „virtual assistant“, „intelligent personal assistant“, „voice-activated personal assistant“, „conversational agent“, „SIRI“, „Alexa“, „Google Assistant“, „Bixby“, „smart loudspeaker“, „Echo“, „smart speaker“ were replaced with the main term “voice assistant”. Also, keywords were standardized to ensure uniformity and consistency (e.g., singular and plural). Further, a few keywords were also deleted from the thesaurus to ensure the focus of the review around the research questions of this study.
Scopus provides Subject Areas—we used these areas to generate the bibliometric analysis (e.g., select CS to analyze all papers from that area). When cleaning the data set—e.g., excluding non-relevant papers—some papers could be assigned to more than one area by checking the author’s affiliation. The co-occurrence networks (Figs. 3–5) of the keywords were obtained automatically from scanning titles, abstracts, and keywords of the articles in the final cleaned datasets. The networks present similarities between frequently co-occurring keywords (themes or topics) in the literature (Van Eck and Waltman, 2010). The co-occurrence number of two keywords is the number of articles that contain both keywords (Van Eck and Waltman, 2014). VOSviewer places these keywords in the network and identifies clusters with similar themes, and with each color representing one cluster (Van Eck and Waltman, 2010). The colors, therefore, reflect topical links and common themes. Boundaries between these clusters are fluid: ‘affordance’ for example (in Fig. 4) is in the light green cluster denoting research on VA systems—but it is also connected to the red cluster, discussing security issues (compare Fig. 4). The assignment to the ‘green cluster happens based on more frequent links to this topic. The co-occurrence networks for our three scholarly disciplines are displayed in Figs. 3–5. By discussing the clusters, nine topic themes for our research emerged (compare next section).
We can see that the networks and the topics covered differ in the three scientific areas. By studying and grouping the research topics that were revealed in the co-occurrence analysis within and across scientific areas, we identified nine thematic clusters in VA research. We labeled these clusters as “Smart devices” (cluster 1), “Human–computer interaction (HCI) and user experience (UX)” (cluster 2), “Privacy and technology adoption” (cluster 3), “VA marketing strategies” (cluster 4), “Technical challenges in VA applications development” (cluster 5), “Potential future VAs and augmented reality (AR) applications and developments” (cluster 6), “Efficiency increase by VA use” (cluster 7), “VAs providing legal evidence” (cluster 8) and “VAs supporting assisted living” (cluster 9). The clusters emerged from discussing the different research areas displayed in Figs. 3–5 in relation to our research question on strategies around VA solutions in private households. Essentially, the process of finding appropriate clusters for our research involved scanning the research areas, listening, and discussing possible grouping until the four researchers of this paper agreed on a final set of nine clusters. The nine clusters encompass different areas and terms in the figures—e.g., cluster 1 (smart devices) covered the areas ‚virtual assistants‘, ‚conversational agents‘, ‚intelligent assistants‘, ‚home automation‘, and ‚smart speakers‘, ‚smart technology‘. Cluster 2 (HCI and UX) includes areas such as ‘voice user interfaces’, ‘chatbots’, ‘human–computer interaction’, ‘hand-free speakers’. Some of the clusters we identified in this process contained only a small number of areas, such as cluster 4 (marketing strategies), which essentially covers the research areas ‘marketing’ and ‘advertising’.
Data analysis step 2: Qualitative content analysis
It can be difficult to derive qualitative conclusions from quantitative data, which is why, in this study, we additionally conducted a qualitative content analysis of the 267 articles in the cleaned dataset. The objective of this second step was to rigorously assess the results from the bibliometric review, ensuring that the identified nine themes identified in stage 1 are in accordance with the main tenets presented in the literature. Any qualitative content analysis of literature suffers, to a certain extent, from the subjective opinions of the authors. However, the benefits of this method are indisputable and follow a well-established approach used in past studies of a similar kind. To counter the risk of subjectivity in data analysis, we involved three researchers in it, thereby triangulating investigators (Denzin, 1989; Flick, 2009). We adopted Krippendorff’s (2013) content analysis methodology to ensure a robust analysis and help with the contextual dimensions of each research field.
In the first step, the nine clusters identified by using VOSViewer were evaluated by the three researchers independently by assigning each of the 267 articles to one of the nine thematic clusters. During this process, it became apparent that the qualitative content analysis confirmed the bibliometric analysis to a large extent, i.e., that most of the articles belonged to the clusters proposed in the bibliometric analysis. However, we excluded 60 articles in this process step, since many of the less obvious thematic mismatches of the articles can only be found in a more in-depth cleaning of the data set: 5 were duplicates (4 allocated to CS, 1 to SS) and 55 papers (46 from CS, 2 from SS and 6 from BMS) were not about VAs in private households. This left us with an overall sample of 207 articles (see the list in the Appendix).
Moreover, we identified articles that belonged to other clusters than suggested in the bibliometric analysis, and assigned them, after discussions with the research team, to the correct cluster. For example, the bibliometric analyses had originally not classified any of the articles in cluster 2 (“HCI and UX”) as belonging to the BMS area, while we identified such articles during the qualitative content analysis. Table 4 below displays the distribution of articles in the final dataset.
After having accomplished this data cleaning, we developed short summary descriptions summarizing the content of the research in each of the nine clusters (see section “Thematic clusters in recent VA research”).
In a final step, we condensed the nine clusters into four meaningful streams, representing distinguishable VA research topics that can support the emergence of interdisciplinary perspectives in research that studies VAs in private households. We applied the following procedure to obtain clusters and allocate papers from the clusters to the streams: First, three researchers independently conceptualized topical research streams. Then, all researchers discussed these streams and agreed on topical headlines reflecting the terminology used in the respective research. Next, they allocated—again first working independently and later together—papers to the four research streams presented in chapter 5. Our aim of finding meaningful streams that can support the emergence of interdisciplinary research on VA in private households made a qualitative procedure appear to be the most appropriate strategy for this step in the analysis. Qualitative analysis helps organize data in meaningful units (Miles and Huberman, 1994).
Thematic clusters in recent VA research
From our analysis, recent research on VA in private households can be divided into nine thematic clusters. In the following, we briefly present these clusters and elaborate on connections between the contributions from the three research areas we considered.
Cluster 1: Smart device solutions
Cluster 1 comprises publications on smart device solutions in smart home settings and their potential in orchestrating various household devices (Amit et al., 2019). Many CS papers present prototypes of web-based smart home solutions that can be controlled with voice commands, like household devices enabling location-independent access to IoT-based systems (Thapliyal et al., 2018; Amit et al., 2019; Jabbar et al., 2019). A research topic that appears in both the CS and SS areas relates to users’ choices, decisions, and concerns (Pridmore and Mols, 2020). Concerns studied relate to privacy issues (Burns and Igou, 2019) or the impact of VA use on different age groups of children (Sangal and Bathla, 2019).
A topic researched in all three scientific domains is the potential of VAs for overcoming the limitations of home automation systems. CS papers typically cover suggestions for resolving mainly technical limitations, such as those concerning language options (Pyae and Scifleet, 2019), wireless transmission range (Jabbar et al., 2019), security (Thapliyal et al., 2018; Parkin et al., 2019), learning from training with humans (Demidova, 2018), or sound-based context information (Alrumayh et al., 2019). SS research mostly investigates the limitations of VAs in acting as an interlocutor and social contact for humans (Lopatovska and Oropeza, 2018; Hoy, 2018; Pridmore and Mols, 2020), or identifies requirements for more user-friendly and secure systems (Vishwakarma et al., 2019). Finally, BMS papers focus on studying efficiency gains from using VAs, for example in the context of saving energy (Vishwakarma et al., 2019).
Cluster 2: Human–computer interaction and user experience
Cluster 2 contains human–computer interaction (HCI) research on the users’ experience of VA technology. Researchers investigate user challenges that result from unmet expectations concerning VA-enabled services (Santos-Pérez et al., 2011; Han et al., 2018; Komatsu and Sasayama, 2019). Papers from the SS area are typically discussing language issues (Principi et al., 2013; King et al., 2017).
A central topic covered both in the CS and BMS publications is trust in and user acceptance of VAs (e.g., Hamill, 2006; Hashemi et al., 2018; Lackes et al., 2019). From the BMS perspective, researchers find that trust and perceived (dis)advantages are factors influencing user decisions on buying or utilizing VAs (Lackes et al., 2019). Complementary, CS researchers find that the usefulness of human-VA interactions and access to one’s own household data impacts the acceptance of VAs (e.g., Pridmore and Mols, 2020). The combination of these two scientific disciplines discussing a topic without SS entering the debate is unique in our data material.
‘Humanized VAs’ is a topic discussed both in CS and SS research. In CS, this includes quasi-human voice-enabled assistants acting as buddies or companions for older adults living alone (Tsiourti et al., 2018a, b) or technical challenges with implementing human characteristics (Hamill, 2006; Lopatovska and Oropeza, 2018; Jacques et al., 2019). Two papers from both CS and SS contributed to the theory of anthropomorphism in the VA context (Lopatovska and Oropeza, 2018; Pradhan et al., 2019). SS additionally offers findings about user needs, like the preferred level of autonomy and anthropomorphism for VAs (Hamill, 2006).
Cluster 3: Privacy and technology adoption
Cluster 3 consists predominantly of CS research into privacy-related aspects like the security risks of VA technology and corresponding technical solutions to minimize them (e.g., Dörner, 2017; Furey and Blue, 2018; Pradhan et al., 2019; Sudharsan et al., 2019). An exception concerns the user-perceived privacy risks and concerns that are studied in all three scientific domains. Related papers discuss these topics with a focus on user attitudes towards VA technology, resulting in technology adoption, and identify factors motivating VA application (e.g., Demidova, 2018; Fruchter and Liccardi, 2018; Lau et al., 2018; Pridmore and Mols, 2020): Perceived privacy risks are found to negatively influence user adoption rates (McLean and Osei-Frimpong, 2019). In CS studies, researchers predominantly propose solutions for more efficient VA solutions that users would want to bring into their homes (Seymour, 2018; Parkin et al., 2019; Vishwakarma et al., 2019). These should be equipped with standardized frameworks for data collection and processing (Bytes et al., 2019), or with technological countermeasures and detection features to establish IoT security and privacy protection (Stadler et al., 2012; Sudharsan et al., 2019; Javed and Rajabi, 2020). Complementary, SS researchers investigate measures for protecting the privacy of VA users beyond technical approaches, such as legislation ensuring privacy protection (Pfeifle, 2018; Dunin-Underwood, 2020).
Cluster 4: VA marketing strategies
Cluster 4 comprises research developing strategies for advertising the use of VAs in private households. We find here articles exclusively from BMS. Scholars address various aspects of VA marketing strategies, such as highlighting security improvements or enhanced user-friendliness and intelligence of the devices (e.g., Burns and Igou, 2019; Vishwakarma et al., 2019). Others study how to measure user satisfaction with VA technology (e.g., Hashemi et al., 2018).
Cluster 5: Technical challenges in VA applications development
Cluster 5 contains predominantly CS research papers investigating and proposing solutions for technical challenges in VA application development. Recent work focuses on extensions and improvements for the technologically relatively mature mass-market VAs (e.g., Liciotti et al., 2014; Azmandian et al., 2019; Jabbar et al., 2019; Mavropoulos et al., 2019). Some research investigates ways to overcome the technical challenges of VAs in household environments: For example, King et al. (2017) work on more robust speech recognition, and Ito (2019) proposes an audio watermarking technique to avoid the misdetection of utterances from other VAs in the same room. Further research on technological improvements includes work on knowledge graphs (Dong, 2019), on cross-lingual dialog scenarios (Liu et al., 2020), on fog computing for detailed VA data analysis (Zschörnig et al., 2019), and on the automated integration of new services based on formal specifications and error handling via follow-up questions (Stefanidi et al., 2019).
We identify a complementarity between CS and SS research within the research topic of “affective computing”. In both research domains, researchers strive to identify ways to create more empathic VAs. For example, Tao et al., (2018) propose a framework that conceptualizes several dimensions of emotion and VA use. SS research contributes to a virtual caregiver prototype aware of the patient’s emotional state (Tironi et al., 2019). However, scholarly contributions in the two areas are not related to each other.
Cluster 6: Potential future VA applications and developments
Cluster 6 investigates the future of VAs research, particularly technological advancements we can expect and suggestions for future research avenues. Most CS papers introduce prospective potential technical applications in many different areas, such as medical treatment and therapy (Shamekhi et al., 2017; Pradhan et al., 2018; Patel and Bhalodiya, 2019) or VA content creation and retrieval (Martin, 2017; Kita et al., 2019). A sub-group of papers also proposes functional prototypes (e.g., Yaghoubzadeh et al., 2015; Freed et al., 2016; Tielman et al., 2017).
We identify three topics that are discussed in both SS and CS publications. The first focuses on language and VAs and represents an area where CS research relates to SS findings: While SS identifies open language issues in dialogs with VAs (Martin, 2017; Ong et al., 2018; Huxohl, et al., 2019), CS researchers investigate how to approach them - not only at the technological level of speech recognition but also in terms of what it means to have a conversation with a machine (Yaghoubzadeh et al., 2015; Ong et al., 2018; Santhanaraj and Barkathunissa, 2020). A second focus is on near-future use scenarios (Hoy, 2018; Seymour, 2018; Tsiourti et al., 2019; Burns and Igou, 2019) such as VA library services, VA services for assisted living or support VAs for emergency detection and handling. The third common topic is about identifying future differences between the use of VAs in private households and in other environments like public spaces (Lopatovska and Oropeza, 2018; Robinson et al., 2018).
Cluster 7: Efficiency increase by VA use
Cluster 7 consists of papers about efficiency increase through VA use—with a focus on smart home automation systems. Papers in BMS discuss the increasing efficiency of home automation systems through the use of VAs (Vishwakarma et al., 2019). CS papers study and appraise the efficiency of home automation solutions and use cases, more efficient VA automation systems, interface device solutions (Liciotti et al., 2014; Jabbar et al., 2019; Jacques et al., 2019), effective activity assistance (Freed et al., 2016; Palumbo et al., 2016; Tielman et al., 2017), care for elderly people (Donaldson et al., 2005; Wallace and Morris, 2018; Tsiourti et al., 2019), and smart assistive user interfaces and systems of the future (Shamekhi et al., 2017; Pradhan et al., 2018; Mokhtari et al., 2019). SS has not yet contributed to this cluster.
Cluster 8: VAs providing legal evidence
Cluster 8 addresses the rather novel topic of digital forensics in papers from the CS and SS domains. The research studies how VA activities can inform court cases. Researchers investigate which information can be gathered, derived, or inferred from IoT-collected data, and what approaches and tools are available and required to analyze them (Shin et al., 2018; Yildirim et al., 2019).
Cluster 9: VAs supporting assisted living
Cluster 9 comprises papers on VAs supporting assisted living. CS papers explore and describe technical solutions for the application of VAs in households and everyday task planning (König et al., 2016; Tsiourti et al., 2018a; Sanders and Martin-Hammond, 2019), for improving aspects of companionship (Donaldson et al., 2005), for stress management in relation to chronic pain (Shamekhi et al., 2017), and for the recognition of distress calls (Principi et al., 2013; Liciotti et al., 2014). CS scholars also study user acceptance and the usability of VA for elderly people (Kowalski et al., 2019; Purao and Meng, 2019).
CS and SS both share a research focus on VAs helping people maintain a self-determined lifestyle (Yaghoubzadeh et al., 2015; Mokhtari et al., 2019) and on their potential and limitations for home care-therapy (Lopatovska and Oropeza, 2018; Kowalski et al., 2019; Turner-Lee, 2019), but without relating findings to each other.
Analysis and conceptualization of research streams
When comparing the bibliometric and the qualitative content analysis, the clusters found in the bibliometric analysis were confirmed to a large extent. The comparison did, however, also lead to the allocation of some articles to different areas. The content analysis particularly helped subsume the nine clusters in four principal research streams. The overview that we gained based on the four streams points to interdisciplinary research topics that need to be studied by scholars wanting to help realize VA potential through applications perceived as safe by users.
What all research domains share to a certain extent is a focus on users’ perceived privacy risks and concerns and a focus on the impact of perceived risks or concerns on the adoption of VA technology. At the same time, our findings confirm our assumption that these complementarities are generally not well used for advancing the field: In CS, researchers predominantly study future application development and technological advancements, but—except for language issues (cluster 6)—they do not relate this much to solving challenges identified in SS and BMS research. In the following, we first present an overview of the four deduced research streams and, in the next section, propositions and the conceptual model for future interdisciplinary research that we developed based on our analysis.
The four major research streams into which we consolidated the identified nine thematic clusters from our literature review are labeled as “Conceptual foundation of VA research” (stream 1), ”Systemic challenges, enabling technologies and implementation” (stream 2),” Efficiency” (stream 3) and “VA applications and (potential) use cases” (stream 4). The streams were obtained in a qualitative procedure, where three researchers conceptualized streams independently and discussed potentially meaningful streams together (compare 3.3). Table 5 provides an overview of the four main streams identified in VA literature and presents selected publications for each of the streams.
The streams systematize the scattered body of VA research in a way that offers clearly distinguishable interdisciplinary research avenues to assist in strategizing around and realizing VA technology potential with applications that are perceived as safe and make a real difference in the everyday life of users. The first stream includes all papers offering theoretical and conceptual knowledge. Papers, for example, conceptualize challenges for VA user perceptions or develop security and privacy protection concepts. Systemic challenges and enabling technologies to form a second stream in VA research. This particularly includes systemic security and UX challenges, and legal issues. Efficiency presents the third research stream, in which scholars particularly investigate private people’s awareness of how VA can make their homes more efficient and asks how VA can be advertised to private households. Finally, VA applications and potential use cases form a fourth research stream. It investigates user expectations and presents prototypes for greater VA use in future home automation systems, medical care, or IOT forensics.
The overview that we gain based on the four streams enables us to frame the contributions of the research domains to VA research more clearly than based on the nine clusters. We find that all research areas contribute publications in all streams. However, the number of contributions varies: CS acts as the main driver of current developments with most publications in all research streams. CS research predominantly addresses systemic challenges, enabling technologies and technology implementation. We recognize increasing scholarly attention on user-oriented VA applications and on VA systems for novel applications beyond their originally intended usage—such as exploiting the microphone array for sensing a user’s gestures and tracking exercises (Agarwal et al., 2018; Tsiourti et al., 2018a/b), or using VA data for forensics (Dorai et al., 2018; Shin et al., 2018)—which indicates that the fundamental technical challenges in the development of this emergent technology are solved. SS so far mainly contributed to the theoretical foundation of VA design principles and use affordance (Yusri et al., 2017), and with the theory that supports developing concrete applications. It also conceptualizes the potential or desirable impact of VA in real-life settings, such as increasing the comfort and quality of life through low-cost smart home automation systems combining VA and smartphones (Kodali et al., 2019), or VA adding to content creation (Martin, 2017). The contributions by BMS scholars are mainly aimed at researching and promoting efficiency increases from using VAs.
Discussion: Propositions and a framework for future research, and related business opportunities
In this paper, we used a systematic literature review approach combining a bibliometric and qualitative content analysis to structure the dispersed insights from scholarly research on VAs in CS, SS, and BMS, and to conceptualize linkages and common themes between them. We identified four major research streams and specified the contributions of researchers from the different disciplines to them in a conceptual overview. Our research allows us to confirm advances in the technological foundations of VAs (Pyae and Joelsson, 2018; Lee et al., 2019; McLean and Osei-Frimpong, 2019), and some concrete VAs like Alexa, Google, and Siri have already arrived in the mass market. Still, more technologically robust and user-friendly solutions that meet their legal requirements for data security will be needed to spark broader user interest (Kuruvilla, 2019; Pridmore and Mols, 2020).
Propositions for future research
We find that recent research from the three domains contributes to the challenges that literature identified as hindering a broader user adaption of VA in different ways, and with different foci. Table 6 summarizes the identified challenges and domain-specific research contributions.
However, to advance VA’s adoption in private households. more complex VA solutions will need to convince users that the perceived privacy risks are solved (Kowalczuk, 2018; Lackes et al., 2019). To this end, all three research domains will need to contribute: CS is required to come up with defining comprehensible frameworks for data collection and processing (Bytes et al., 2019), and solutions to ensure data safety (Mirzamohammadi et al., 2017; Sudharsan et al., 2019; Javed and Rajabi, 2020). Complementary, SS should identify the social and legal conditions which users perceive as safe environments for VA use in private households (Pfeifle, 2018; Dunin-Underwood, 2020). Finally, BMS is urged to identify user advantages that go beyond simple efficiency gains, investigate the benefits of accessing one’s own data and find metrics for user trust in technology applications (Lackes et al., 2019). Particularly, SS research is providing potentially valuable insights into users’ perceptions and use case areas such as home medical care or assisted living that would be worth to be taken into account by CS scholars developing advanced solutions, and vice versa benefit from taking available technical solutions into consideration. Similarly, BMS scholarly research exhibits a rather narrow focus on increasing the efficiency of activities by using VA applications, and on how to market these solutions to private households. CS scholars complement this focus with technical solutions aimed at increasing the efficiency of automated home systems, but the research efforts from the two domains are not well aligned. VA security-related issues and solutions, limitations of VA applications for assisted living, and effects of humanization and anthropomorphism seem to be under-investigated topics in BMS.
Thus, our first proposition reads as follows:
Proposition 1: To advance users' adoption of complex VA applications in private households, domain-specific disciplinary efforts of CS, SS, and BMS need to be integrated by interdisciplinary research.
Our study has shown that this is particularly important to arrive at the necessary insights into how to overcome VA security issues and VA technological development constraints CS works on and, at the same time, deal with the effects of VA humanization (SS research) and develop VA-related business opportunities (BMS research) in smart home systems, assisted living, medical home therapy, and digital forensic. Therefore, we define the following three sub-propositions:
Proposition 1.1: In order to realize VA potential for medical care solutions that are perceived as safe by users, research insights from studies on VA perception and on perceived security issues from SS need to be integrated with CS research aimed at resolving the technical constraints of VA applications and with BMS research about the development of use cases desirable for private households and related business models.
Proposition 1.2: To advance smart home system efficiency and arrive at regulations that make users perceive the usage of more complex applications as safe, research insights from studies on systemic integration, and security-related technical solutions from CS need to be studied and developed.
Proposition 1.3: In order to increase our knowledge of social and economic conditions for VA adoption in private households, BMS and SS research needs to integrate insights from research with users with VA prototypes and research about near-future scenarios of VA use to model and test valid business cases that are not based on mere assumptions of efficiency gains.
In our four streams, we moreover recognize a common interest in studying VAs beyond isolated voice-enabled ‘butlers’. In essence, VAs are increasingly investigated as gateways to smart home systems which are enabling interaction with entire ecosystems. This calls, next to the development of more complex technical applications in CS, mainly for more future research into the social (SS) and economical (BMS) conditions enabling the emergence of such ecosystems—from the necessary changes in regulations to insurance and real estate issues to designing marketing strategies for VA health applications in the home (Olson and Kemery, 2019; Bhat, 2005; Melkers and Xiao, 2010; Sestino et al., 2020). The above is not only true for the three scientific domains which we looked at, but also calls for the integration of complementary VA-related research in adjacent disciplines, such as law, policy, or real estate. Our second proposition thus reads as follows:
Proposition 2: To advance users’ adoption of complex VA applications in private households, research needs to perform interdisciplinary efforts to study and develop ways to overcome ecosystem-related technology adoption challenges.
Conceptual framework for future research
As outlined above, future research wishing to contribute to increasing user acceptance and awareness and to generate use cases that make sense for private households in everyday life is urged to make interdisciplinary efforts to integrate complementary findings.
The conceptual framework (Fig. 6) presents avenues for future research. The figure highlights Propositions 1 and 2 that emphasize the need to advance user adaptation through interdisciplinary research that can help overcome challenges from complex VA applications (Proposition 1) and ecosystem-related technology adoption challenges (Proposition 2), to advance users’ adoption of complex VA applications. Furthermore, the figure reflects three sub-propositions that summarize relevant avenues for interdisciplinary work that can help solve VA-related security issues, generate security and privacy protection concepts, and advance frameworks for legal regulations. The first sub-propositions is research that helps find solutions for home medical care where VA limitations and security issues are solved. Sub-proposition 2 consists of research needed to advance systemic integration and security-related solutions for efficiency and the regulation of smart home systems. The third sub-proposition involves research that can help define social and economic conditions for VA and create business opportunities by including insights from user research with VA prototypes and from research with near-future scenarios that can model and test valid business cases that are not based on mere assumptions of efficiency gains.
Identified business opportunities that will help realize VA potential
Overall, we confirm that VA is not a technology that enables companies to profit from implementing it in their own organizations or make business processes more efficient like other technological innovations (Bhat, 2005; Chao et al., 2007; Sestino et al., 2020). Instead, we find that companies need to build business models around VA-related products and services that users perceive as safe and beneficial. Table 7 below provides an overview of potential areas providing such business opportunities, the technology maturity of these areas, and social and business-related challenges, which need to be solved to fully access VA potential for the everyday life of users.
As shown, the three areas where we identified business opportunities from literature, i.e. smart home systems (Freed et al., 2016; Thapliyal et al., 2018; Jabbar et al., 2019), assisted living and medical home therapy (König et al., 2016; Tsiourti et al., 2018a/b; Sanders and Martin-Hammond, 2019), and digital forensics (Shin et al., 2018; Yildirim et al., 2019) exhibit different technology, social system conditions, and business model maturity models. It is relevant to say that, although in our review, cluster 8 ‘digital forensics’ consisted of only two papers, we can expect this to be an increasingly salient cluster in the next few years due to the importance of the topic for governmental bodies and society.
Designing appropriate business models will require companies, in the first step, to develop a deep understanding of the potential design of future ecosystems, i.e. of “the evolving set of actors, activities, and artifacts, including complementary and substitute relations, that are important for the innovative performance of an actor or a population of actors.” (Granstrand and Holgersson, 2020, p. 3). We here call for interdisciplinary research that develops and integrates the necessary insights in a thorough and, for companies, comprehensible manner.
Methodology
In this paper, we used a relatively new approach to a literature review: We combined an automated bibliometric analysis with qualitative content analysis to gain holistic insights into a multi-faceted research topic and to structure the available body of knowledge across three scientific domains. In doing so, we followed the advice in recent research that found the classical, purely content-based literature reviews to be time-consuming, lacking rigor, and prone to be affected by the researchers’ biases (Caputo et al., 2018; Verma and Gustafsson, 2020). Overall, we can confirm that automating literature research through VOSviewer turned out to be a time-saver regarding the actual search across (partly domain-specific) sources and the collection of scientific literature, and it allowed us to relatively quickly identify meaningful research clusters based on keywords in an enormous body of data (Verma, 2017; Van Eck and Waltman, 2014). However, we also found that several additional steps were necessary to assuring the quality of the review: Despite the careful selection of keywords, the initial literature list contained several irrelevant articles (i.e., not addressing VA-related topics, yet involving the keywords ‘echo’ and ‘home’).
Thus, manual cleaning of the literature lists was required before meaningful graphs could be generated by VOSviewer. The consequent step of identifying research clusters from the graphs demanded broad topical expertise. We found this identification of clusters to be—as described by Krippendorff (2013)—a necessarily iterative process, not only to continuously refine meaningful clusters but also to reach a common understanding and interpretation in an interdisciplinary team. In a similar vein, deriving higher-level categories, i.e. the research streams, turned out to require iterative refinements.
Retrospectively, the quantitative bibliometric analysis helped in recognizing both core topics and gaps in VA-related research with comprehensive reach. The complementary content analysis yielded insights into intersections and overlaps in research by the different areas considered and enabled the identification of further promising avenues for interdisciplinary research.
Conclusions
From our study, we conclude that research into VA-based services is not taking advantage of the potential synergies across disciplines. Business opportunities can specifically be found in spaces that require the combination of research domains that are still disconnected. This should be taken into account when looking for information that can help predict the service value of smart accommodation (Papagiannidis and Davlembayeva, 2022) or characteristics of future technology use cases that can fit users’ needs (Nguyen et al., 2022). This can also support scholars and managers in strategizing about future business opportunities (Brem et al., 2019; Antonopoulou and Begkos, 2020).
In consequence, our framework and the propositions we developed highlight the fact that more interdisciplinary research is needed and what type of research is needed to advance the development and application of VA in private households and, by implication, inform companies about future business opportunities.
The study also provides concrete future characteristics of VA use cases technology: Constant development in research on VAs, e.g., on novel devices and complementary technology like artificial intelligence and virtual reality, suggests that future VAs will no longer be limited to audio-only devices, but increasingly feature screens and built-in cameras, and offer more advanced use cases. Accordingly, embodied VAs in the form of for example social robots, require further technology advancement and integration, and studies on user perception.
Implications for managers
Our research enabled us to identify and describe the most promising areas for business opportunities while highlighting related technological, social, and business challenges. From this, it became obvious that managers need to take all three dimensions and related types of challenges into account in order to successfully predict characteristics of future technology use cases that fit users’ needs, and use this information for their strategy development processes (Brem et al., 2019; Antonopouloua and Begkos, 2020). This requires not just the design of new services and business models, but of complete business ecosystems, and the establishment of partnerships from the private sector. We moreover found that establishing trust in the safe and transparent treatment of privacy and data is key in getting users to buy and use services involving VA, while pure efficiency-based arguments are not enough to dispel current worries of potential users, like the data security of technology used to improve the tracking and monitoring of patients or viruses (Abdel-Basset et al., 2021).
Although our study investigated VAs in private households, with the growing acceptance of working from home, not the least due to the experiences made in the COVID-19 pandemic, our findings also have implications for organizing homework environments. While, for example, the Alexa “daily check” and Apple health check app can provide a community-based AI technology that can support self-testing and virus tracking efforts (Abdel-Basset et al., 2021), managers will need to ensure that company data is safe, and this will require them to consider how their employees use VA hardware at home.
Limitations
As with most research, this study has its limitations. While we see value in the combined approach taken in this research, as it allows insights around strategies for VA solutions that match the needs of private households, limitations can be seen in the qualitative approach of our methodology, which is subject to a certain degree of author subjectivity. Limitations of our work also relate to the fact that we included only articles from the Scopus database in this review. Thus, future research should consider articles published in other databases like EBSCO, Web of Science, or Google Scholar. Also, the study focused on only three scientific domains up to May 2020. This review paper does not offer a discussion of the consequences of the ongoing changes triggered by the Covid-19 pandemic for the use of VA solutions in private households. The impact of this disruptive pandemic experience on the use of VA is not yet well understood. More research will be necessary to obtain a complete account of how Covid-19 transformed the use of VA in private homes today and to help understand the linkages and intersections between further research areas using the same methodology.
The combined bibliometric and qualitative content analysis provided an overview of connections and intersections, and an in-depth overview of current research streams. Future research could conduct co-citation and/or bibliographic coupling analyses of authors, institutions, countries, references, etc. to complement our research.
Data availability
Datasets were derived from public resources. Data sources for this article are provided in the Methods section of this article. Data analysis documents are not publicly available as researchers have moved on to other institutions.
References
Abdel-Basset M, Chang V, Nabeeh NA (2021) An intelligent framework using disruptive technologies for COVID-19 analysis. Technol Forecast Soc Change 163:120431. https://doi.org/10.1016/j.techfore.2020.120431
Agarwal A, Jain M, Kumar P, Patel S (2018) Opportunistic sensing with MIC arrays on smart speakers for distal interaction and exercise tracking. In: IEEE Press (ed), 2018 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP). pp. 6403–6407
Alrumayh AS, Lehman SM, Tan CC (2019) ABACUS: audio based access control utility for smarthomes. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 4th ACM/IEEE Symposium on Edge Computing. pp. 395–400
Amit S, Koshy AS, Samprita S, Joshi S, Ranjitha N (2019) Internet of Things (IoT) enabled sustainable home automation along with security using solar energy. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 International Conference on Communication and Electronics Systems (ICCES). pp. 1026–1029
Ammari T, Kaye J, Tsai J, Bentley F (2019) Music, search, and IoT: how people (really) use voice assistants. ACM Trans Comput–Hum Interact 26:1–28. https://doi.org/10.1145/3311956
Antonopoulou K, Begkos C (2020) Strategizing for digital innovations: value propositions for transcending market boundaries. Technol Forecast Soc Change 156:120042
Aylett MP, Cowan BR, Clark L (2019) Siri, echo and performance: you have to suffer darling. In: Association for Computing Machinery (ACM) (ed), Extended Abstracts of the 2019 CHI Conference on Human Factors in Computing Systems. pp. 1–10
Azmandian M, Arroyo-Palacios J, Osman S (2019) Guiding the behavior design of virtual assistants. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 19th ACM international conference on intelligent virtual agents. pp. 16–18
Batat W (2021) How augmented reality (AR) is transforming the restaurant sector: Investigating the impact of “Le Petit Chef” on customers’ dining experiences. Technol Forecast Soc Change 172:121013
Bhat JSA (2005) Concerns of new technology based industries—the case of nanotechnology. Technovation 25(5):457–462. https://doi.org/10.1016/j.technovation.2003.09.001
Berg Insight (2022) The number of smart homes in Europe and North America reached 105 million in 2021, Press Releases, 20 April 2022. https://www.berginsight.com/the-number-of-smart-homes-in-europe-and-north-america-reached-105-million-in-2021
Birgonul Z, Carrasco O (2021) The adoption of multidimensional exploration methodology to the design-driven innovation and production practices in AEC industry. J Constr Eng Manag Innov 4(2):92–10. https://doi.org/10.31462/jcemi.2021.02092105
Brandt M (2018) Wenig echo in Deutschland. Statista
Brasser F, Frassetto T, Riedhammer K, Sadeghi A-R, Schneider T, Weinert C (2018) VoiceGuard: secure and private speech processing. In: International Speech Communication Association (ISCA) (ed), Proceedings of the annual conference of the International Speech Communication Association, INTERSPEECH. pp. 1303–1307
Brause SR, Blank G (2020) Externalized domestication: smart speaker assistants, networks and domestication theory. Inf Commun Soc 23(5):751–763. https://doi.org/10.1080/1369118X.2020.1713845
Brem A, Bilgram V, Marchuk A (2019) How crowdfunding platforms change the nature of user innovation–from problem solving to entrepreneurship. Technol Forecast Soc Change 144:348–360
Brenner W, Giffen BV, Koehler J (2021) Management of artificial intelligence: feasibility, desirability and viability. In: Aier S et al. (eds), Engineering the transformation of the enterprise. pp. 15–36
Burns MB, Igou A (2019) “Alexa, write an audit opinion”: adopting intelligent virtual assistants in accounting workplaces. J Emerg Technol Account 16(1):81–92. https://doi.org/10.2308/jeta-52424
Bytes A, Adepu S, Zhou J (2019) Towards semantic sensitive feature profiling of IoT devices. IEEE Internet Things J 6(5):8056–8064. https://doi.org/10.1109/JIOT.2019.2903739
Calaça J, Nóbrega L, Baras K (2019) Smartly water: Interaction with a smart water network. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of the 2019 5th Experiment International Conference (Exp. at’19). pp. 233–234
Callahan JL (2014) Writing literature reviews: a reprise and update. Hum Resour Dev Rev 13(3):271–275. https://doi.org/10.1177/1534484314536705
Caputo A, Ayoko OB, Amoo N (2018) The moderating role of cultural intelligence in the relationship between cultural orientations and conflict management styles. J Bus Res 89:10–20. https://doi.org/10.1016/j.jbusres.2018.03.042
Carayannis EG, Turner E (2006) Innovation diffusion and technology acceptance: the case of PKI technology. Technovation 26(7):847–855. https://doi.org/10.1016/j.technovation.2005.06.013
Celebre AMD, Dubouzet AZD, Medina IBA, Surposa ANM, Gustilo RC (2015) Home automation using raspberry Pi through Siri enabled mobile devices. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2015 International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment and Management (HNICEM). pp. 1–6
Chan ZY, Shum P (2018) Smart office: a voice-controlled workplace for everyone. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2nd international symposium on computer science and intelligent control. pp. 1–5
Chao C-C, Yang J-M, Jen W-Y (2007) Determining technology trends and forecasts of RFID by a historical review and bibliometric analysis from 1991 to 2005. Technovation 27(5):268–279. https://doi.org/10.1016/j.technovation.2006.09.003
Clark M, Newman MW, Dutta P (2022) ARticulate: one-shot interactions with intelligent assistants in unfamiliar smart spaces using augmented reality. Proc ACM Interact Mob Wearable Ubiquitous Technol 6(1):1–24
Clemente C, Greco E, Sciarretta E, Altieri L (2022) Alexa, how do i feel today? Smart speakers for healthcare and wellbeing: an analysis about uses and challenges. Sociol Soc Work Rev 6(1):6–24
Columbus, L (2020) What’s new in Gartner’s hype cycle for emerging technologies, 2020. Forbes. https://www.forbes.com/sites/louiscolumbus/2020/08/23/whats-new-in-gartners-hype-cycle-for-emerging-technologies-2020/?sh=6363286fa46a
Demidova E (2018) Can children teach AI? Towards expressive human–AI dialogs. In: Vrandečić D, Bontcheva K, Suárez-Figueroa MC, Presutti V, Celino I, Sabou M, Kaffee L-A, Simperl E (eds), International Semantic Web Conference Proceedings (P&D/Industry/BlueSky). p. 2180
Denzin NK (1989) Interpretive biography, vol. 17. SAGE
Dercole F, Dieckmann U, Obersteiner M, Rinaldi S (2008) Adaptive dynamics and technological change. Technovation 28(6):335–348. https://doi.org/10.1016/j.technovation.2007.11.004
Deshpande NG, Itole DA (2019) Personal assistant based home automation using Raspberry Pi. Int J Recent Technol Eng
Donaldson J, Evnin J, Saxena S (2005) ECHOES: encouraging companionship, home organization, and entertainment in seniors. In: Association for Computing Machinery (ACM) (ed), Proceedings of the CHI’05 extended abstracts on human factors in computing systems. pp. 2084–2088
Dong XL (2019) Building a broad knowledge graph for products. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of the 2019 IEEE 35th International Conference on Data Engineering (ICDE), 2019-April. pp. 25–25
Dorai G, Houshmand S, Baggili I (2018) I know what you did last summer: Your smart home internet of things and your iPhone forensically ratting you out. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 13th international conference on availability, reliability and security. Article 3232814
Dörner R (2017) Smart assistive user interfaces in private living environments. In: Gesellschaft für Informatik e.V. (GI) (ed), Lecture notes in informatics (LNI), proceedings—series of the gesellschaft fur informatik (GI). pp. 923–930
Drucker PF (1988) The coming of the new organization. Reprint Harvard Business Review, 88105. https://ams-forschungsnetzwerk.at/downloadpub/the_coming-of_the_new_organization.pdf. Accessed 10 Jul 2022
Druga S, Williams R, Breazeal C, Resnick M (2017) “Hey Google is it OK if I eat you?” Initial explorations in child-agent interaction. In: Blikstein P, Abrahamson D (eds), Proceedings of the 2017 conference on Interaction Design and Children (IDC ’17). pp. 595–600
Dunin-Underwood A (2020) Alexa, can you keep a secret? Applicability of the third-party doctrine to information collected in the home by virtual assistants. Inf Commun Technol Law 29(1):101–119. https://doi.org/10.1080/13600834.2020.1676956
Elahi H, Wang G, Peng T, Chen J (2019) On transparency and accountability of smart assistants in smart cities. Appl Sci 9(24):5344. https://doi.org/10.3390/app9245344
Fathalizadeh A, Moghtadaiee V, Alishahi M (2022) On the privacy protection of indoor location dataset using anonymization. Comput Secur 117:102665
Flick U (2009) An introduction to qualitative research, 4th edn. SAGE
Freed M, Burns B, Heller A, Sanchez D, Beaumont-Bowman S (2016) A virtual assistant to help dysphagia patients eat safely at home. IJCAI 2016:4244–4245
Fruchter N, Liccardi I (2018) Consumer attitudes towards privacy and security in home assistants. In: Association for Computing Machinery (ACM) (ed), Extended Abstracts of the 2018 CHI conference on human factors in computing systems, 2018-April. pp. 1–6
Furey E, Blue J (2018) She knows too much—voice command devices and privacy. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of 2018 29th Irish Signals and Systems Conference (ISSC). pp. 1–6
Gartner (2019) Gartner predicts 25 percent of digital workers will use virtual employee assistants daily by 2021. Gartner https://www.gartner.com/en/newsroom/press-releases/2019-01-09-gartner-predicts-25-percent-of-digital-workers-will-u
Giorgi R, Bettin N, Ermini S, Montefoschi F, Rizzo A (2019) An iris+voice recognition system for a smart doorbell. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 8th Mediterranean Conference on Embedded Computing (MECO). pp. 1–4
Gnewuch U, Morana S, Heckmann C, Maedche A (2018) Designing conversational agents for energy feedback. In: Chatterjee S, Dutta K, Sundarraj RP (eds), Proceedings of the International conference on design science research in information systems and technology, vol 10844. pp. 18–33
Gong Y, Yatawatte H, Poellabauer C, Schneider S, Latham S (2018) Automatic autism spectrum disorder detection using everyday vocalization captured by smart devices. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2018 ACM international conference on bioinformatics, computational biology, and health informatics. pp. 465–473
Goud N, Sivakami A (2019) Spectate home appliances by internet of things using MQTT and IFTTT through Google Assistant. Int J Sci Technol Res 8(10):1852–1857
Granstrand O, Holgersson M (2020) Innovation ecosystems: a conceptual review and a new definition. Technovation 90:102098
Grossman GM, Helpman E (1991) Innovation and growth in the global economy. MIT Press
Grossman-Kahn B, Rosensweig R (2012) Skip the silver bullet: driving innovation through small bets and diverse practices. Lead Through Design 18:815
Hamill L (2006) Controlling smart devices in the home. Inf Soc 22(4):241–249. https://doi.org/10.1080/01972240600791382
Han J, Chung AJ, Sinha MK, Harishankar M, Pan S, Noh HY, Zhang P, Tague P (2018) Do you feel what I hear? Enabling autonomous IoT device pairing using different sensor types. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2018 IEEE symposium on Security and Privacy (SP). pp. 836–852
Harzing A-W, Alakangas S (2016) Google Scholar, Scopus and the Web of Science: a longitudinal and cross-disciplinary comparison. Scientometrics 106(2):787–804. https://doi.org/10.1007/s11192-015-1798-9
Hashemi SH, Williams K, El Kholy A, Zitouni I, Crook PA (2018) Measuring user satisfaction on smart speaker intelligent assistants using intent sensitive query embeddings. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 27th ACM international conference on information and knowledge management. pp. 1183–1192
Hern A (2017) Google Home smart speaker brings battle of living rooms to UK. The Guardian. https://www.theguardian.com/technology/2017/mar/28/google-home-smart-speaker-launch-uk
Herring H, Roy R (2007) Technological innovation, energy efficient design and the rebound effect. Technovation 27(4):194–203. https://doi.org/10.1016/j.technovation.2006.11.004
Hofmann C, Orr S (2005) Advanced manufacturing technology adoption—the German experience. Technovation 25(7):711–724. https://doi.org/10.1016/j.technovation.2003.12.002
Hoy MB (2018) Alexa, Siri, Cortana, and more: an introduction to voice assistants. Med Ref Serv Q 37(1):81–88. https://doi.org/10.1080/02763869.2018.1404391
Hu J, Tu X, Zhu G, Li Y, Zhou Z (2013) Coupling suppression in human target detection via impulse through wall radar. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of the 2013 14th International Radar Symposium (IRS), vol 2. pp. 1008–1012
Huxohl T, Pohling M, Carlmeyer B, Wrede B, Hermann T (2019) Interaction guidelines for personal voice assistants in smart homes. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 international conference on Speech Technology and Human–Computer Dialogue (SpeD). pp. 1–10
IDEO.org (2009) Human-centred design toolkit. IDEO.org
Ichikawa J, Mitsukuni K, Hori Y, Ikeno Y, Alexandre L, Kawamoto T, Nishizaki Y, Oka N (2019) Analysis of how personality traits affect children’s conversational play with an utterance-output device. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 Joint IEEE 9th International Conference on Development and Learning and Epigenetic Robotics (ICDL-EpiRob). pp. 215–220
Ilievski A, Dojchinovski D, Ackovska N, Kirandziska V (2018) The application of an air pollution measuring system built for home living. In: Kalajdziski S, Ackovska N (eds) ICT innovations 2018. Engineering and life sciences. Springer, pp. 75–89
Ito A (2019) Muting machine speech using audio watermarking. In: Pan J-S, Ito A, Tsai P-W, Jain LC (eds) Recent advances in intelligent information hiding and multimedia signal processing. Springer, pp. 74–81
Jabbar WA, Kian TK, Ramli RM, Zubir SN, Zamrizaman NS, Balfaqih M, Shepelev V, Alharbi S (2019) Design and fabrication of smart home with internet of things enabled automation system. IEEE Access 7:144059–144074. https://doi.org/10.1109/ACCESS.2019.2942846
Jacques R, Følstad A, Gerber E, Grudin J, Luger E, Monroy-Hernández A, Wang D (2019) Conversational agents: acting on the wave of research and development. In: Association for Computing Machinery (ACM) (ed), Extended Abstracts of the 2019 CHI conference on human factors in computing systems. pp. 1–8
Javed Y, Rajabi N (2020) Multi-Layer perceptron artificial neural network based IoT botnet traffic classification. In: Arai K, Bhatia R, Kapoor S (eds) Proceedings of the Future Technologies Conference (FTC) 2019. Springer, pp. 973–984
Jones VK (2018) Voice-activated change: marketing in the age of artificial intelligence and virtual assistants. J Brand Strategy 7(3):233–245
Kandlhofer M, Steinbauer G, Hirschmugl-Gaisch S, Huber P (2016) Artificial intelligence and computer science in education: from kindergarten to university. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2016 IEEE Frontiers in Education Conference (FIE). pp. 1–9
Kerekešová V, Babič F, Gašpar V (2019) Using the virtual assistant Alexa as a communication channel for road traffic situation. In: Choroś K, Kopel M, Kukla E, Siemiński A (eds) Multimedia and network information systems, vol 833. Springer, pp. 35–44
Khattar S, Sachdeva A, Kumar R, Gupta R (2019) Smart home with virtual assistant using Raspberry Pi. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 9th International conference on cloud computing, data science & engineering (Confluence). pp. 576–579
King B, Chen I-F, Vaizman Y, Liu Y, Maas R, Parthasarathi SHK, Hoffmeister B (2017) Robust speech recognition via anchor word representations. In: International Speech Communication Association (ISCA) (ed), Proceedings of the Interspeech 2017. pp. 2471–2475
Kita T, Nagaoka C, Hiraoka N, Dougiamas M (2019) Implementation of voice user interfaces to enhance users’ activities on Moodle. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of 2019 4th international conference on information technology. pp. 104–107
Kodali RK, Rajanarayanan SC, Boppana L, Sharma S, Kumar A (2019) Low cost smart home automation system using smart phone. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 IEEE R10 Humanitarian Technology Conference (R10-HTC)(47129). pp. 120–125
Komatsu S, Sasayama M (2019) Speech error detection depending on linguistic units. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2019 3rd international conference on natural language processing and information retrieval. pp. 75–79
König A, Francis LE, Malhotra A, Hoey J (2016) Defining Affective Identities in elderly nursing home residents for the design of an emotionally intelligent cognitive assistant. In: Favela J, Matic A, Fitzpatrick G, Weibel N, Hoey J (eds) Proceedings of the 10th EAI International Conference on Pervasive Computing Technologies for Healthcare. ICST, pp. 206–210
Kortum SS (1997) Research, patenting, and technological change. Econometrica 1389–1419. https://doi.org/10.2307/2171741
Kowalczuk P (2018) Consumer acceptance of smart speakers: a mixed methods approach. J Res Interact Mark 12(4):418–431. https://doi.org/10.1108/JRIM-01-2018-0022
Kowalski J, Jaskulska A, Skorupska K, Abramczuk K, Biele C, Kopeć W, Marasek K (2019) Older adults and voice interaction: a pilot study with Google Home. In: Extended abstracts of the 2019 CHI conference on human factors in computing systems. pp. 1–6
Krippendorff K (2013) Content analysis: an introduction to its methodology. SAGE
Krotov V (2017) The Internet of Things and new business opportunities. Gener Potential Emerg Technol 60(6):831–841. https://doi.org/10.1016/j.bushor.2017.07.009
Kumar A (2018) AlexaPi3—an economical smart speaker. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2018 IEEE Punecon. pp. 1–4
Kumar N, Lee SC (2022) Human–machine interface in smart factory: a systematic literature review. Technol Forecast Soc Change 174:121284
Kunath G, Hofstetter R, Jörg D, Demarchi D (2019) Voice first barometer Schweiz 2018. Universität Luzern, pp. 1–25
Kuruvilla R (2019) Between you, me, and Alexa: on the legality of virtual assistant devices in two-party consent states. Wash Law Rev 94(4):2029–2055
Lackes R, Siepermann M, Vetter G (2019). Can I help you?—the acceptance of intelligent personal assistants. In: Pańkowska M, Sandkuhl K (eds) Perspectives in business informatics research. Springer, pp. 204–218
Lau J, Zimmerman B, Schaub F (2018) Alexa, are you listening?: Privacy perceptions, concerns and privacy-seeking behaviors with smart speakers. Proc ACM Hum–Comput Interact 2:1–31. https://doi.org/10.1145/3274371. (CSCW)
Leahey E, Beckman CM, Stanko TL (2017) Prominent but less productive: The impact of interdisciplinarity on scientists’ research. Adm Sci Q 62(1):105–139. https://doi.org/10.1177/0001839216665364
Lee I, Kinney CE, Lee B, Kalker AA (2009) Solving the acoustic echo cancellation problem in double-talk scenario using non-gaussianity of the near-end signal. In: Association for Computing Machinery (ACM) (ed), International conference on independent component analysis and signal separation. pp. 589–596
Lee S, Kim S, Lee S (2019) “What does your agent look like?” A drawing study to understand users’ perceived persona of conversational agent. In: Association for Computing Machinery (ACM) (ed), Extended abstracts of the 2019 CHI conference on human factors in computing systems. pp. 1–6
Li S, Garces E, Daim T (2019) Technology forecasting by analogy-based on social network analysis: the case of autonomous vehicles. Technol Forecast Soc Change 148:119731. https://doi.org/10.1016/j.techfore.2019.119731
Li W, Chen Y, Hu H, Tang C (2020) Using granule to search privacy preserving voice in home IoT systems. IEEE Access 8:31957–31969. https://doi.org/10.1109/ACCESS.2020.2972975
Liciotti D, Ferroni G, Frontoni E, Squartini S, Principi E, Bonfigli R, Zingaretti P, Piazza F (2014) Advanced integration of multimedia assistive technologies: a prospective outlook. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Proceedings of the 2014 IEEE/ASME 10th international conference on Mechatronic and Embedded Systems and Applications (MESA). pp. 1–6
Liu Z, Shin J, Xu Y, Winata GI, Xu P, Madotto A, Fung P (2020) Zero-shot cross-lingual dialogue systems with transferable latent variables. ArXiv. https://arxiv.org/pdf/1911.04081.pdf
Lopatovska I, Oropeza H (2018) User interactions with “Alexa” in public academic space. Proceedings of the Association for Information Science and Technology 55(1):309–318. https://doi.org/10.1002/pra2.2018.14505501034
Lopatovska I, Rink K, Knight I, Raines K, Cosenza K, Williams H, Sorsche P, Hirsch D, Li Q, Martinez A (2019) Talk to me: exploring user interactions with the Amazon Alexa. J Librariansh Inf Sci 51(4):984–997. https://doi.org/10.1177/0961000618759414
Lovato SB, Piper AM, Wartella EA (2019) Hey Google, do unicorns exist? Conversational agents as a path to answers to children’s questions. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 18th ACM international conference on interaction design and children. pp. 301–313
Miles MB, Huberman AM (1994) Qualitative data analysis. A source book of new methods, 2nd edn. Sage
Macdonald RJ, Jinliang W (1994) Time, timeliness of innovation, and the emergence of industries. Technovation 14(1):37–53. https://doi.org/10.1016/0166-4972(94)90069-8
Malik KM, Malik H, Baumann R (2019) Towards vulnerability analysis of voice-driven interfaces and countermeasures for replay attacks. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 IEEE conference on Multimedia Information Processing and Retrieval (MIPR). pp. 523–528
Martin EJ (2017) How Echo, Google Home, and other voice assistants can change the game for content creators. EContent. http://www.econtentmag.com/Articles/News/News-Feature/How-Echo-Google-Home-and-Other-Voice-Assistants-Can-Change-the-Game-for-Content--Creators-116564.htm
Masutani O, Nemoto S, Hideshima Y (2019) Toward a better IPA experience for a connected vehicle by means of usage prediction. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), Qualitative data analysis. A source book of new methods, 2nd edn2019 IEEE International Conference on Pervasive Computing and Communications Workshops (PerCom Workshops). pp. 681–686
Mavropoulos T, Meditskos G, Symeonidis S, Kamateri E, Rousi M, Tzimikas D, Papageorgiou L, Eleftheriadis C, Adamopoulos G, Vrochidis S, Kompatsiaris I (2019) A context-aware conversational agent in the rehabilitation domain. Futur Internet 11(11):231. https://doi.org/10.3390/fi11110231. Article
McLean G, Osei-Frimpong K (2019) Hey Alexa… examine the variables influencing the use of artificial intelligent in-home voice assistants. Comput Hum Behav 99:28–37. https://doi.org/10.1016/j.chb.2019.05.009
McReynolds E, Hubbard S, Lau T, Saraf A, Cakmak M, Roesner F (2017) Toys that listen: a study of parents, children, and internet-connected toys. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2017 CHI conference on human factors in computing systems. pp. 5197–5207
Melkers J, Xiao F (2010) Boundary-spanning in emerging technology research: determinants of funding success for academic scientists. J Technol Transf 37(3):251–270. https://doi.org/10.1007/s10961-010-9173-8
Mirzamohammadi S, Chen JA, Sani AA, Mehrotra S, Tsudik G (2017) Ditio: trustworthy auditing of sensor activities in mobile and IoT devices. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 15th ACM conference on embedded network sensor systems
Moher D, Liberati A, Tetzlaff J, Altman DG, Prisma Group (2009) Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. PLoS Med 6(7):e1000097. https://doi.org/10.1371/journal.pmed.1000097. Article
Mokhtari M, de Marassé A, Kodys M, Aloulou H (2019) Cities for all ages: Singapore use case. In: Stephanidis C, Antona M (eds) HCI international 2019—late breaking posters. Springer, pp. 251–258
Nguyen TH, Waizenegger L, Techatassanasoontorn AA (2022) “Don’t Neglect the User!”–Identifying Types of Human-Chatbot Interactions and their Associated Characteristics. Inf Syst Front 24(3):797–838
Oh S-R, Kim Y-G (2017) Security requirements analysis for the IoT. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2017 International conference on Platform Technology and Service (PlatCon). pp. 1–6
Olson C, Kemery K (2019) 2019 Voice report: from answers to action: Customer adoption of voice technology and digital assistants. Technical report. Microsoft
Omale G (2020) Customer service and support leaders can use this Gartner Hype Cycle to assess the maturity and risks of customer service and support technologies. Gartner. https://www.gartner.com/smarterwithgartner/5-trends-drive-the-gartner-hype-cycle-for-customer-service-and-support-technologies-2020/
Ong DT, De Jesus CR, Gilig LK, Alburo JB, Ong E (2018) A dialogue model for collaborative storytelling with children. In: Yang JC, Chang M, Wong L-H, Rodrigo MM (eds), 26th International conference on computers in education workshop on innovative technologies for enhancing interactions and learning. pp. 205–210
Palumbo F, Gallicchio C, Pucci R, Micheli A (2016) Human activity recognition using multisensor data fusion based on reservoir computing. J Ambient Intell Smart Environ 8(2):87–107. https://doi.org/10.3233/AIS-160372
Papagiannidis S, Davlembayeva D (2022) Bringing Smart Home Technology to Peer-to-Peer Accommodation: Exploring the Drivers of Intention to Stay in Smart Accommodation. Inf Syst Front 24(4):1189–1208
Parkin S, Patel T, Lopez-Neira I, Tanczer L (2019) Usability analysis of shared device ecosystem security: Informing support for survivors of IoT-facilitated tech-abuse. In: Association for Computing Machinery (ACM) (ed), Proceedings of the new security paradigms workshop. pp. 1–15
Patel D, Bhalodiya P (2019) 3D holographic and interactive artificial intelligence system. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 International Conference on Smart Systems and Inventive Technology (ICSSIT). pp. 657–662
Patnaik D, Becker R (1999) Needfinding: the why and how of uncovering people’s needs. Design Manag J (Former Ser) 10(2):37–43
Petticrew M, Roberts H (2006) Systematic reviews in the social sciences: a practical guide. John Wiley & Sons
Pfeifle A (2018) Alexa, what should we do about privacy: protecting privacy for users of voice-activated devices. Wash Law Rev 93:421
Porter ME (1990) Competitive advantage of nations. Competitive Intell Rev 1(1):14
Portillo CD, Lituchy TR (2018) An examination of online repurchasing behavior in an IoT environment. In: Simmers CA, Anandarajan M (eds) The Internet of People, Things and Services: workplace tranformations. Routledge, pp. 225–241
Pradhan A, Findlater L, Lazar A (2019) “Phantom friend” or “just a box with information”: personification and ontological categorization of smart speaker-based voice assistants by older adults. In: Association for Computing Machinery (ACM) (ed), Proceedings of the ACM on Human–Computer Interaction, 3(CSCW)
Pradhan A, Mehta K, Findlater L (2018) “Accessibility came by accident”: use of voice-controlled intelligent personal assistants by people with disabilities. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2018 CHI conference on human factors in computing systems. pp. 1–13
Pridmore J, Mols A (2020) Personal choices and situated data: privacy negotiations and the acceptance of household intelligent personal assistants. Big Data Soc 7(1):205395171989174. https://doi.org/10.1177/2053951719891748. Article
Principi E, Squartini S, Piazza F, Fuselli D, Bonifazi M (2013) A distributed system for recognizing home automation commands and distress calls in the Italian language. INTERSPEECH, pp. 2049–2053
Purao S, Meng C (2019) Data capture and analyses from conversational devices in the homes of the elderly. In: Guizzardi G, Gailly F, Suzana R, Pitangueira Maciel (eds) Lecture notes in computer science, vol 11787. Springer, pp. 157–166
Purington A, Taft JG, Sannon S, Bazarova NN, Taylor SH (2017) “Alexa is my new BFF”: social roles, user satisfaction, and personification of the Amazon Echo. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2017 CHI conference extended abstracts on human factors in computing systems. pp. 2853–2859
Pyae A, Joelsson TN (2018) Investigating the usability and user experiences of voice user interface: a case of Google home smart speaker. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 20th international conference on human-computer interaction with mobile devices and services adjunct. pp. 127–131
Pyae A, Scifleet P (2019) Investigating the role of user’s English language proficiency in using a voice user interface: a case of Google Home smart speaker. In: Association for Computing Machinery (ACM) (ed), (Extended Abstracts of the 2019 CHI Conference on Human Factors in Computing Systems—CHI EA ’19. pp. 1–6
Rabassa V, Sabri O, Spaletta C (2022) Conversational commerce: do biased choices offered by voice assistants’ technology constrain its appropriation? Technol Forecast Soc Change 174:121292
Robinson S, Pearson J, Ahire S, Ahirwar R, Bhikne B, Maravi N, Jones M (2018) Revisiting “hole in the wall” computing: private smart speakers and public slum settings. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 2018 CHI conference on human factors in computing systems. pp. 1–11
Robledo-Arnuncio E, Wada TS, Juang B-H (2007) On dealing with sampling rate mismatches in blind source separation and acoustic echo cancellation. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2007 IEEE workshop on applications of signal processing to audio and acoustics. pp. 34–37
Rzepka C, Berger B, Hess T (2022) Voice assistant vs. Chatbot–examining the fit between conversational agents’ interaction modalities and information search tasks. Inf Syst Front 24(3):839–856
Saadaoui FZ, Mahmoudi C, Maizate A, Ouzzif M (2019) Conferencing-Ng protocol for Internet of Things. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 Third international conference on Intelligent Computing in Data Sciences (ICDS). pp. 1–5
Samarasinghe N, Mannan M (2019a) Towards a global perspective on web tracking. Comput Secur 87:101569. https://doi.org/10.1016/j.cose.2019.101569
Samarasinghe N, Mannan M (2019b) Another look at TLS ecosystems in networked devices vs. web servers. Comput Secur 80:1–13. https://doi.org/10.1016/j.cose.2018.09.001
Sanders J, Martin-Hammond A (2019) Exploring autonomy in the design of an intelligent health assistant for older adults. In: Association for Computing Machinery (ACM) (ed), Proceedings of the 24th International conference on intelligent user interfaces: companion. pp. 95–96
Sangal S, Bathla R (2019) Implementation of restrictions in smart home devices for safety of children. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 4th International Conference on Information Systems and Computer Networks (ISCON). pp. 139–143
Santhanaraj K, Barkathunissa A (2020) A study on the factors affecting usage of voice assistants and the interface transition from touch to voice. Int J Adv Sci Technol 29(5):3084–3102
Santos-Pérez M, González-Parada E, Cano-García JM (2011) AVATAR: an open source architecture for embodied conversational agents in smart environments. In: Bravo J, Hervás R, Villarreal V (eds) Ambient Assisted living. Springer, pp. 109–115
Sestino A, Prete MI, Piper L, Guido G (2020) Internet of Things and Big Data as enablers for business digitalization strategies. Technovation 98:102173. https://doi.org/10.1016/j.technovation.2020.102173. Article
Seymour W (2018) How loyal is your Alexa? Imagining a respectful smart assistant. In: Association for Computing Machinery (ACM) (ed), Extended abstracts of the 2018 CHI conference on human factors in computing systems. pp. 1–6
Shamekhi A, Bickmore T, Lestoquoy A, Gardiner P (2017) Augmenting group medical visits with conversational agents for stress management behavior change. In: de Vries PW, Oinas-Kukkonen H, Siemons L, Beerlage-de Jong N, van Gemert-Pijnen L (eds) Persuasive technology: development and implementation of personalized technologies to change attitudes and behaviors. Springer, pp. 55–67
Shank DB, Wright D, Nasrin S, White M (2022) Discontinuance and restricted acceptance to reduce worry after unwanted incidents with smart home technology. Int J Hum–Comput Interact 1–14. https://doi.org/10.1080/10447318.2022.2085406
Shin C, Chandok P, Liu R, Nielson SJ, Leschke TR (2018) Potential forensic analysis of IoT data: an overview of the state-of-the-art and future possibilities. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2017 IEEE International Conference on Internet of Things (IThings) and IEEE Green Computing and Communications (GreenCom) and IEEE Cyber, Physical and Social Computing (CPSCom) and IEEE Smart Data (SmartData). pp. 705–710
Singh V, Verma S, Chaurasia SS (2020) Mapping the themes and intellectual structure of corporate university: co-citation and cluster analyses. Scientometrics 122(3):1275–1302. https://doi.org/10.1007/s11192-019-03328-0
Solorio JA, Garcia-Bravo JM, Newell BA (2018) Voice activated semi-autonomous vehicle using off the shelf home automation hardware. IEEE Internet Things J 5(6):5046–5054. https://doi.org/10.1109/JIOT.2018.2854591
Souden M, Liu Z (2009) Optimal joint linear acoustic echo cancelation and blind source separation in the presence of loudspeaker nonlinearity. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2009 IEEE international conference on multimedia and expo. pp. 117–120
Srikanth S, Saddamhussain SK, Siva Prasad P (2019) Home anti-theft powered by Alexa. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 International conference on Vision Towards Emerging Trends in Communication and Networking (ViTECoN). pp. 1–6
Stefanidi Z, Leonidis A, Antona M (2019) A multi-stage approach to facilitate interaction with intelligent environments via natural language. In: Stephanidis C, Antona M (eds) HCI International 2019—Late Breaking Posters, vol 1088. Springer, pp. 67–77
Struckell E, Ojha D, Patel PC, Dhir A (2021) Ecological determinants of smart home ecosystems: A coopetition framework. Technol Forecast Soc Change 173:121147. https://doi.org/10.1016/j.techfore.2021.121147
Sudharsan B, Corcoran P, Ali MI (2019) Smart speaker design and implementation with biometric authentication and advanced voice interaction capability. In: Curry E, Keane M, Ojo A, Salwala D (eds), Proceedings for the 27th AIAI Irish Conference on Artificial Intelligence and Cognitive Science, NUI Galway, vol 2563. pp. 305–316
Tao F, Liu G, Zhao Q (2018) An ensemble framework of voice-based emotion recognition system. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2018 First Asian Conference on Affective Computing and Intelligent Interaction (ACII Asia). pp. 1–6
Thapliyal H, Ratajczak N, Wendroth O, Labrado C (2018) Amazon Echo enabled IoT home security system for smart home environment. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2018 IEEE International Symposium on Smart Electronic Systems (ISES) (Formerly INiS). pp. 31–36
Tielman ML, Neerincx MA, Bidarra R, Kybartas B, Brinkman W-P (2017) A therapy system for post-traumatic stress disorder using a virtual agent and virtual storytelling to reconstruct traumatic memories. Journal of Medical Systems 41(8):125. https://doi.org/10.1007/s10916-017-0771-y
Tironi A, Mainetti R, Pezzera M, Borghese AN (2019) An empathic virtual caregiver for assistance in exer-game-based rehabilitation therapies. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 IEEE 7th International Conference on Serious Games and Applications for Health (SeGAH). pp. 1–6
Trenholm R (2016) Amazon Echo (and Alexa) arrive in Europe, and Echo comes in white now too. CNET. https://www.cnet.com/news/amazon-echo-and-alexa-arrives-in-europe/
Tsiourti C, Weiss A, Wac K, Vincze M (2019) Multimodal integration of emotional signals from voice, body, and context: effects of (in)congruence on emotion recognition and attitudes towards robots. Int J Soc Robot 11(4):555–573. https://doi.org/10.1007/s12369-019-00524-z
Tsiourti C, Quintas J, Ben-Moussa M, Hanke S, Nijdam NA, Konstantas D (2018a) The CaMeLi framework—a multimodal virtual companion for older adults. In: Kapoor S, Bhatia R, Bi Y (eds) Studies in computational intelligence, vol 751. Springer, pp. 196–217
Tsiourti C, Ben-Moussa M, Quintas J, Loke B, Jochem I, Lopes JA, Konstantas D (2018b) A virtual assistive companion for older adults: design implications for a real-world application. In: Sharma H, Shrivastava V, Bharti KK, Wang L (eds), Lecture notes in networks and systems, vol 15. Springer, pp. 1014-1033
Tung L (2018) Amazon Echo, Google Home: how Europe fell in love with smart speakers. ZDnet. https://www.zdnet.com/article/amazon-echo-google-home-how-europe-fell-in-love-with-smart-speakers
Turner-Lee N (2019) Can emerging technologies buffer the cost of in-home care in rural America? Generations 43(2):88–93. http://web.a.ebscohost.com/ehost/pdfviewer/pdfviewer?vid=2&sid=0aaaf704-d3bd-42ab-ad26-ecd36c0a059b%40sdc-v-sessmgr02
Vaca K, Gajjar A, Yang X (2019) Real-time automatic music transcription (AMT) with Zync FPGA. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 IEEE Computer Society Annual Symposium on VLSI (ISVLSI). pp. 378–384
Van Eck NJ, Waltman L (2014) Visualizing bibliometric networks. In: Ding Y, Roussea R, Wolfram D (eds) Measuring scholarly impact: methods and practice. Springer, pp. 285–320
Van Eck NJ, Waltman L (2010) Software survey: VOSviewer, a computer program for bibliometric mapping. Scientometrics 84(2):523–538
Verma S, Gustafsson A (2020) Investigating the emerging COVID-19 research trends in the field of business and management: a bibliometric analysis approach. J Bus Res 118:253–261
Verma S (2017) The adoption of big data services by manufacturing firms: an empirical investigation in India. J Inf Syst Technol Manag 14(1):39–68
Vishwakarma SK, Upadhyaya P, Kumari B, Mishra AK (2019) Smart energy efficient home automation system using IoT. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 4th International Conference on Internet of Things: smart Innovation and Usages (IoT-SIU). pp. 1–4
Vora J, Tanwar S, Tyagi S, Kumar N, Rodrigues JJPC (2017) Home-based exercise system for patients using IoT enabled smart speaker. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2017 IEEE 19th International Conference on E-Health Networking, Applications and Services (Healthcom). pp. 1–6
Wakefield CC (2019) Achieving position 0: optimising your content to rank in Google’s answer box. J Brand Strategy 7(4):326–336
Wallace T, Morris J (2018) Identifying barriers to usability: smart speaker testing by military veterans with mild brain injury and PTSD. In: Langdon P, Lazar J, Heylighen A, Dong H (eds) Breaking down barriers. Springer, pp. 113–122
Xi N, Hamari J (2021) Shopping in virtual reality: a literature review and future agenda. J Bus Res 134:37–58. https://doi.org/10.1016/j.jbusres.2021.04.075
Yaghoubzadeh R, Pitsch K, Kopp S (2015) Adaptive grounding and dialogue management for autonomous conversational assistants for elderly users. In: Brinkman W-P, Broekens J, Heylen D (eds) Intelligent virtual agents, vol 9238. Springer, pp. 28–38
Yildirim İ, Bostancı E, Güzel MS (2019) Forensic analysis with anti-forensic case studies on Amazon Alexa and Google Assistant build-in smart home speakers. In: Institute of Electrical and Electronics Engineers (IEEE) (ed), 2019 4th International conference on computer science and engineering (UBMK). pp. 271–273
Yusri MM, Kasim S, Hassan R, Abdullah Z, Ruslai H, Jahidin K, Arshad MS (2017) Smart mirror for smart life. In: Institute of Electrical and Electronics Engineers (ed), 2017 6th ICT International Student Project Conference (ICT-ISPC) 2017 6th ICT International Student Project Conference (ICT-ISPC). pp. 1–5
Zschörnig T, Wehlitz R, Franczyk B (2019) A fog-enabled smart home analytics platform. In: Brodsky A, Hammoudi S, Filipe J, Smialek M (eds) Proceedings of the 21st International Conference on Enterprise Information Systems (ICEIS 2019), vol 1. SciTePress, pp. 604–610
Zuboff S (2019) The age of surveillance capitalism: the fight for a human future at the new frontier of power. Profile Books
Harwood S, Eaves S (2020) Conceptualising technology, its development and future: The six genres of technology. Technol Forecast Soc Change 160:120174
Stadler S, Riegler S, Hinterkörner S (2012) Bzzzt: When mobile phones feel at home. Conference on Human Factors in Computing Systems – Proceedings, 1297-1302. https://doi.org/10.1145/2212776.2212443
Acknowledgements
This research was funded by the Swiss National Science Foundation (SNSF) as part of the project “VA-People, Experiences, Practices and Routines” (VA-PEPR) (Grant Nr. CRSII5_189955). We are grateful for the support from the wider project team from Lucerne University of Applied Sciences and Arts, Eastern Switzerland University of Applied Sciences, and Northumbria University. We would also like to thank Bjørn S. Cience for his support while working on this paper.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Ethical approval
The article does not contain any studies with human participants performed by any of the authors.
Informed consent
The article does not contain any studies with human participants performed by any of the authors.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Minder, B., Wolf, P., Baldauf, M. et al. Voice assistants in private households: a conceptual framework for future research in an interdisciplinary field. Humanit Soc Sci Commun 10, 173 (2023). https://doi.org/10.1057/s41599-023-01615-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1057/s41599-023-01615-z