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Computer-supported cooperative work

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General process of interaction and cooperation with CSCW technology

Computer-supported cooperative work (CSCW) is the study of how people utilize technology collaboratively, often towards a shared goal. CSCW addresses how computer systems can support collaborative activity and coordination.[1] More specifically, the field of CSCW seeks to analyze and draw connections between currently understood human psychological and social behaviors and available collaborative tools, or groupware.[2] Often the goal of CSCW is to help promote and utilize technology in a collaborative way, and help create new tools to succeed in that goal. These parallels allow CSCW research to inform future design patterns or assist in the development of entirely new tools.

History

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The origins of CSCW as a field are intertwined with the rise and subsequent fall of office automation as response to some of the criticisms, particularly the failure to address the impact human psychological and social behaviors can have.[3] Greif and Cashman created the term CSCW to help employees seeking to further their work with technology. A few years later, in 1987, Charles Findley presented the concept of collaborative learning-work.[4] Computer-supported cooperative work is an interdisciplinary research area of growing interest which relates workstations to digitally advanced networking systems.[5] The first technologies were economically feasible, but their interoperability was lacking which makes understanding a well-tailored supporting system difficult. Due to global markets, more organizations are being pushed to decentralize their corporate systems. When faced with the complexities of today's business issues, a significant effort must be made to improve manufacturing systems' efficiency, improve product quality, and reduce time to market.

The idea of CSCW or computer-supported cooperative work has become useful over the years since its inception and most especially in the ongoing crisis of the COVID-19 pandemic. The measures to mitigate the virus' spread have led to firm closures and increased the rates of remote working and learning. People now share a common workspace, hold virtual meetings, see and hear each other's movements and voices in a common virtual workspace with a group-centered design. Only when advanced and generic methods are combined does a CSCW framework seem complete to the consumer. For decades, CSCW studies have been proposed using a variety of technologies to promote collaborative work, ranging from shared data services to video-mediated networks for synchronous operations. Among the various domains of CSCW, the Audio/Video Conference Module (AVM) has become useful in enabling audiovisual communication via the online applications used to discuss and undertake work operations such as Zoom and EzTalks.

Central concerns and concepts

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CSCW is a design-oriented academic field that is interdisciplinary in nature and brings together librarians, economists, organizational theorists, educators, social psychologists, sociologists, anthropologists and computer scientists, among others. The expertise of researchers in various and combined disciplines help researchers identify venues for possible development. Despite the variety of disciplines, CSCW is an identifiable research field focused on understanding characteristics of interdependent group work with the objective of designing adequate computer-based technology to support such cooperative work.

Essentially, CSCW goes beyond building technology itself and looks at how people work within groups and organizations, as well as the impacts of technology on those processes. CSCW has ushered in a great extent of melding between social scientists and computer scientists. These scientists work together to overcome both technical and non-technical problems within the same user spaces. For example, many R&D professionals working with CSCW are computer scientists who have realized that social factors play an important role in the development of collaborative systems. On the flip side, many social scientists who understand the increasing role of technology in our social world become "technologists" who work in R&D labs developing cooperative systems. Over the years, CSCW researchers have identified a number of core dimensions of cooperative work. A non-exhaustive list includes:

  • Awareness: individuals working together need to be able to gain some level of shared knowledge about each other's activities.[6]
  • Articulation work: cooperating individuals must be able to partition work into units, divide it amongst themselves and, after the work is performed, reintegrate it.[7][8]
  • Appropriation (or tailorability): how an individual or group adapts a technology to their own particular situation; the technology may be appropriated in a manner completely unintended by the designers.[9][10][11]

These concepts have largely been derived through the analysis of systems designed by researchers in the CSCW community, or through studies of existing systems (for example, Wikipedia[12]). CSCW researchers that design and build systems try to address core concepts in novel ways. However, the complexity of a domain can make it difficult to produce conclusive results.

Articulation work

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Articulation work is essentially the work that makes other work exist and possible. It is an effort made to make other work easier, more manageable, and can either be planned or unplanned. Therefore articulation work is an integral part of software process since software processes can sometimes fail or break down. Articulation work is also commonly known as "invisible work" since it is not always noticed. The concept was introduced by Anselm Strauss.[13] He described it as a way to observe the "nature of mutually dependent actors in their division of labour".[14] It was introduced in CSCW by Schmidt and Bannon in 1992, where it would be applied to more realistic work scenarios in society.[14] Articulation work is inherent in collaboration. The idea of articulation work was initially used in relation to computer-supported cooperative work, but it was travelled through other domains of work, such as healthcare.[13] Initially, articulation work was known for scheduling and allocation of resources, but now, extends beyond that. Articulation work can also be seen as the response developers make to adapt to changes due to error or misjudgments in the real world.[15] There are various models of articulation work that help identify applicable solutions to recover or reorganize planned activities. It is also important to note that it can vary depending on the scenario. Oftentimes there is an increase in the need for articulation work as the situation becomes more complex.

Because articulation work is so abstract, it can be split into two categories from the highest level: individual activity and collective activity.[14]

  • With individual activity, articulation work is almost always applicable. It is obvious that the subject is required to articulate his / her own work. But when a subject is faced with a new task, there are many questions that must be answered in order to move forward and be successful. This questioning is considered the articulation work to the actual project; invisible, but necessary. There is also articulation of action within an activity.[15] For example, creating to-do lists and blueprints may be imperative to progressing a project. There is also articulation of operation within an action. In terms of software, the user must have adequate knowledge and skill in using computer systems and knowledge about software in order to perform tasks.[16]
  • In a teamwork setting, articulation is imperative for collective activity. To maximize the efficiency of all the people working, the articulation work must be very solid. Without a solid foundation, the team is unable to collaborate effectively.[17] Furthermore, as the size of the team increases, the articulation work becomes more complex.

What goes in between the user and the system is often overlooked. But software process modeling techniques as well as the model of articulation work is imperative in creating a solid foundation that allows for improvement and enhancement. In a way, all work needs to be articulated; there needs to be a who, what, where, when and how. With technology, there are many tools that utilize articulation work. Tasks such as planning and scheduling can be considered articulation work. There are also times when the articulation work is bridging the gap between the technology and the user. Ultimately, articulation work is the means that allows for cooperative work to be cooperative, a main objective of CSCW.

Matrix

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One of the most common ways of conceptualizing CSCW systems is to consider the context of a system's use. One such conceptualization is the CSCW Matrix, first introduced in 1988 by Johansen; it also appears in Baecker (1995).[18][19] The matrix considers work contexts along two dimensions: whether collaboration is co-located or geographically distributed, and whether individuals collaborate synchronously (same time) or asynchronously (not depending on others to be around at the same time).

Image of CSCW Matrix[18] The image describes each of the section of matrix and lists examples of CSCW applications that relate to that time/space matrix classification.

Same time/same place – face to face interaction

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Same time/different place – remote interaction

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Different time/same place – continuous task (ongoing task)

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  • Team rooms
  • Large displays
  • Post-it
  • War-rooms

Different time/different place – communication and coordination

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This matrix is an outline of CSCW in different contexts, but it does have its limitations for users who are beginners at understanding CSCW. For example, there is a collaborative mode called multi-synchronous that can not fit the matrix.[20] As the field evolves whether by new social standards or technological development, the simple matrix cannot describe all of CSCW and fields of research within.

Model of Coordinated Action (MoCA)

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The Model of Coordinated Action, as a framework for analyzing group collaboration, identifies several dimensions of common features of cooperative work that extend beyond the CSCW matrix and allow for more complexity in describing how teams work given certain conditions. The seven total dimensions that constitute the model (MoCA) are used to describe essential "fields of action" seen in existing CSCW research. Rather than existing as a rigid matrix with distinct quadrants, this model is to be interpreted as multidimensional – each dimension existing as its own continuum. These ends of these dimensions' continuums are defined in the following subsections.[21]

Synchronicity

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This is pertaining to the time at which the collaborative work occurs. This could range from live meetings conducted at exact times to viewing recordings or responding to messages that do not require one or all participants to be active at the time the recording, message, or other deliverable was created.[21]

Physical distribution

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This covers the distance in which team members could be geographically separated while still being able to collaborate. The least physically distributed cooperative work is a meeting in which all team members are physically present in the same space and communicating verbally, face-to-face. Conversely, technology now allows for more distanced communication that could extend as far as meeting from multiple countries.[21]

Scale

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The scale of a collaborative project refers to how many individuals comprise the project team. As the number of people involved increases, the division of tasks must become more intricate and complex to ensure that each participant is contributing in some way.[21]

Number of communities of practice

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A community of practice refers to a group of individuals with shared, common knowledge of a specific subject. This group may be composed of both newcomers and experts. New members will gain knowledge through exposure and immersion and become experts as newer members join, thus expanding the community of practice over time. These groups can be as specific or as broad as their members feel is necessary, as no two people have the same set of knowledge and diversification of perspectives is common.[21]

Nascence

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Some collaborative projects are designed to be more long-lasting than others, often meaning that their standard practices and actions are more established than newer, less developed projects. Synonymous with "newness", nascence refers to how established a cooperative effort is at a given point in time. While most work is always developing in some way, newer projects will have to spend more time establishing common ground among its team members and will thus have a higher level of nascence.[21]

Planned permanence

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This dimension encourages teams to establish common practices, terminology, etc. within the group to ensure cohesion and understanding among the work. It is difficult to gauge how long a project will last, therefore establishing these foundations in early stages helps to prevent confusion between group members at later stages when there may be higher stakes or deeper investigation. The notion of planned permanence is essential to the model as it allows for productive communication between individuals who may have different expertise or are members of different communities of practice.[21]

Turnover

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This dimension is used to describe the rate at which individuals leave a collaborative group. Such events may occur at various rates depending on the impact one's departure may have on the individual and the group. In a well-established collaborative action or a group with a small scale, a team member leaving may have detrimental effects, whereas temporary projects with open membership may have high turnover rates covered by the project's high scale. Crowdsourcing, such as the means by which Wikipedia creates its articles, are an example of an entity with high turnover rates (e.g. a Wikipedian contributes only to one article at one time) that does not face impactful consequences due to the high scale of the collaborative work.[21]

Considerations for interaction design

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Self-presentation

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Online presentation on Zoom platform

Self-presentation has been studied in traditional face-to-face environments, but as society has embraced content culture, social platforms have generated new affordances for presenting oneself online. Due to technological growth, social platforms, and their increased affordances, society has reconfigured the way users self-present online due to audience input and context collapse.[22]

In an online setting, audiences are physically invisible which complicates the users ability to distinguish their intended audience. Audience input, on social platforms, can range from commenting, sharing, liking, tagging, etc.[22] For example, LinkedIn is a platform who encourages commentary where positive feedback outweighs negative feedback on topics including career announcements.[23] Conversely, audience input can be unwarranted which can lead to real-life implications, especially for marginalized groups who are prone to both warranted and unwarranted commentary on public posts.[24]

Context collapse is when separate audiences join together and make curated content for an audience which is visible to unintended audiences.[22] The likelihood of context collapse is especially challenging with the surge of proprietary software which introduces a conflict of interest for the users who have an ideal audience, but the platforms algorithm has a differing one.[23] Collapsed context influences self-presentation when previously separate audiences are merged into one.

Affordance

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As media platforms proliferate, so do the affordances offered that directly influence how users manage their self-presentation. According to researchers, the three most influential affordances on how users present themselves in an online domain include anonymity, persistence, and visibility.[22]

Anonymity in the context of social media refers to the separation of an individual's online and offline identity by making the origin of their messages unspecified.[22] Platforms that support anonymity have users that are more likely to depict their offline self accurately online (i.e Reddit).[22] Comparatively, platforms with less constraints on anonymity are subject to users that portray their online and offline selves differently, thus creating a "persona".[23] Facebook, for example, requires its users to abide by its "real-name" policy, further connecting their offline and online identities.[24] Furthermore, being able to unequivocally associate an online persona to a real-life human contributes to how users present themselves online honestly.[23]

Platforms which have "content persistence" store content so it may be accessed at a later point in time.[23] Platforms including Instagram and Facebook are highly persistent with their ability to make content available until deleted. Whereas, Snapchat has lower persistence because content is ephemeral causing users to post content that represents their offline self more accurately.[22] This affordance strongly affects users' self-presentation management because they recognize content can be openly accessed on platforms that are highly persistent. On social platforms, visibility is created when information is acquired with search of a word or phrase or even topic name, an example being a hashtag.[22] When content is visible, users become aware of their self-presentation and will adjust accordingly.[23] However, some platforms give their users leverage in specifying how visible their content is, thus affording for visibility control.[22][23][24] For example Snapchat and Instagram both allow users to build a "close friends list" and block specific people from viewing content. Nonetheless, intended audiences are never guaranteed. Facebook is an example of a platform that shares content to both primary (e.g. direct friends) and secondary viewers (e.g. friends of friends).[23] The concern of visibility with Facebook's algorithm is notably challenging for marginalized groups because of such blurred visibility mechanisms.[24] In addition, users face privacy concerns relative to visibility given the current era of screenshotting.[22]

Boundary object

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A boundary object is an informational item which is used differently by various communities or fields of study and may be a concrete, physical item or an abstract concept.[25]

Examples of boundary objects include:

  • Most research libraries,[26] as different research groups may use different resources from the same libraries.
  • An interdisciplinary research project, as different business sectors and research groups may have different goals for the project.[27]
  • The outline of a U.S. state's boundaries, which may be drawn on a roadmap for travelers or on an ecological map for biologists.[26]

In computer-supported cooperative work, boundary objects are typically used to study how information and tools are transmitted between different cultures or communities.[25]

Some examples of boundary objects in CSCW research are:

  • Electronic health records, which pass health information between groups with different priorities (such as doctors, nurses, and medical secretaries).[28]
  • The concept of a "digital work environment", as used in Swedish political debate.[29]

Standardization vs. flexibility in CSCW

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Standardization is defined as "agile processes that are enforced as a standard protocol across an organization to share knowledge and best practice."[30] Flexibility, on the other hand, is the "ability to customize and evolve processes to suit the aims of an agile team".[30]

As CSCW tools, standardization and flexibility are almost mutually exclusive from each other. In CSCW, flexibility comes in two forms, flexibility for future change, and flexibility for interpretation.[31] Everything that is done on the internet has a level of standardization due to the internet standards. In fact, Email has its own set of standards, of which the first draft was created in 1977.[32] No CSCW tool is perfectly flexible, and all lose flexibility in the same three levels. Either flexibility is lost when the programmer makes the toolkit, when the programmer makes the application, and/or when the user uses the application.

Standardization in information infrastructure

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Information infrastructure requires extensive standardization to make collaboration work. Since data is transferred from company to company and occasionally nation to nation, international standards have been put in place to make communication of data much simpler. Often one company's data will be included in a much larger system, and this would become almost impossible without standardization. With information infrastructure, there is very little flexibility in potential future changes. Due to the fact that the standards have been around for decades and there are hundreds of them, it is nearly impossible to change one standard without greatly affecting the others.[31]

Flexibility in toolkits

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Creating CSCW toolkits requires flexibility of interpretation; it is important that these tools are generic and can be used in many different ways.[32] Another important part of a toolkit's flexibility is the extensibility, the extent to which new components or tools can be created using the tools provided. An example of a toolkit that is flexible in how generic the tools are is Oval. Oval consists of four components: objects, views, agents, and links. This toolkit was used to recreate four previously existing communication systems: The Coordinator, gIBIS, Lotus Notes, and Information Lens. It proved that, due to its flexibility, Oval was able to create many forms of peer-to-peer communication applications.

Applications

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Applications in education

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There have been three main generations to distance education, starting with the first being through postal service, the second through mass media such as the radio, television, and films, and the third being the current state of e-learning.[33] Technology-enhanced learning, or "e-learning", has been an increasingly relevant topic in education, especially with the development of the COVID-19 pandemic that has caused many schools to switch to remote learning.[34] E-learning is defined as "the use of technology to support and enhance learning practice". It includes the utilization of many different types of information and communication technologies (ICTs) and is limited to the use of intranet and internet in the teaching and learning process.[35] The development of content is mainly through using learning objectives to create activities through Virtual Learning Environments, Content Management Systems, and Learning Management Systems.[35] These technologies have created massive change in their use as CSCW tools, allowing students and teachers to work on the same platforms and have a shared online space in which to communicate in. The delivery of content can be either asynchronous, such as email and discussion forums, or synchronous, like through chat or video conferencing.[35] Synchronous education allows for much more equal interaction between students and instructors and better communication between students for the facilitation of group projects and assignments.[36]

Community of inquiry framework

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E-learning has been explained by the community of inquiry (COI) framework introduced by Garrison et al. In this framework, there are three major elements: cognitive presence, social presence, and teaching presence.

  • Cognitive presence in this framework is the measure of how well meaning is able to be constructed from the content being taught. It assumes that students have access to a large network from which to gain information from.[33] This includes peers, instructors, alumni, and practicing professionals. E-learning has allowed this network to be easily accessible through the internet, and these connections can be made synchronously through video, audio, or texts.
  • Social presence in the community of inquiry framework is how well participants can connect with one another on a social level and present themselves as "real people".[37] Video conferencing has been shown to increase social presence within students.[38] One study found that "social presence in VC [Virtual Conferencing] can have a positive effect on group efficacy and performance by amplifying group cohesion".[39] This information is greatly useful in designing future systems because it explains the importance of technology like video conferencing in synchronous e-learning. Groups that are able to see each other face to face have a stronger bond and are able to complete tasks faster than those without it.[39] Increasing the social presence in online education environments helps facilitate in the understanding of the content and the ability for the group to solve problems.
  • Teaching presence in the COI framework contains two main functions: creation of content and the facilitation of this content.[37] The creation of content is usually done by the instructor, but students and instructors can share the role of facilitator, especially in higher education settings.[37] The goal of teaching presence is "to support and enhance social and cognitive presence for the purpose of realizing educational outcome".[37]

Virtual educational software and tools are becoming more readily used globally. Remote educational platforms and tools must be accessible for various generations, including children as well as guardians or teachers, yet these frameworks are not adapted to be child-friendly. The lack of interface and design consideration for younger users causes difficulty in potential communication between children and older generations utilizing the software. This in turn leads to a decrease in virtual learning participation as well as potential diminished collaboration with peers.[40] In addition, it may be difficult for older teachers to utilize such technology, and communicate with their students. Similar to orienting older workers with CSCW tools, it is difficult to train younger students or older teachers in utilizing virtual technology, and may not be possible for widely spread virtual classrooms and learning environments.

Applications in gaming

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Collaborative mixed reality games modify the shared social experience, during which players can interact in real-time with physical and virtual gaming environments and with other multiplayer video gamers.[41] This may be done through any means of communication, self-representation, and collaboration.

Communication systems

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The group members experience effective communication practices following the availability of a common platform for expressing opinions and coordinating tasks. The technology is applicable not only in professional contexts but also in the gaming world.[42] CSCW usually offers synchronous and asynchronous games to allow multiple individuals to compete in a certain activity across social networks. Thus, the tool has made gaming more interesting by facilitating group activities in real-time and widespread social interactions beyond geographical boundaries.[43]

Self-presentation

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HCI, CSCW, and game studies in MMORPGs highlight the importance of avatar-mediated self-presentation in player experience. These studies have put together known two components of self-presentation in games. First, through personal choice and personalization of avatars, various social values (such as gender roles and social norms) are integrated and reflected in the player's self-image. Second, self-presentation in games conjointly options experimentation of fully new identities or reaffirmation of existing identities. This includes cross-gender play and queerness gameplay.[44] Computer-mediated communication in gaming settings takes place across different channels, which can consist of structured message systems, bulletin boards, meeting rooms, and shared diaries.[42] As such, the players can hold conversations while proceeding with the game to create a lively experience. Thus, the features of video games offer a platform for users to openly express themselves.

Collaborations and game design in multi-user video games

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The most collaborative and socially interactive aspect of a video game is the online communities. Popular video games often have various social groups for their diverse community of players. For example, in the quest-based multiplayer game World of Warcraft, the most collaborative and socially interactive aspect of the game are the "Guilds", which are alliances of individuals with whom players must join forces.[45] By incorporating Guilds, World of Warcraft creates opportunities for players to work together with their team members who can be from anywhere in the world. WOW players who are associated with a Guild are more likely to play and do quests with the same Guild mates each time which develops a strong bond between players and a sense of community.[45] These bonds and friendships formed from playing with Guild mates, not only improves collaboration within the game, it also creates a sense of belonging and community which is one of the most important attribute of online gaming communities.

When it comes to designing a multi-user collaborative game, it involves positive interdependence, personal accountability, and social skills.[46] Positive Interdependence is the dependence of collaboration from members of a group in order to accomplish a task. In video games, this is the idea of players on a team or in a group understanding that working together is beneficial, and that the success and failure of the group is shared equally if all members participate.[46] An example of including a positive interdependence aspect to a video game is creating a common shared goal for the team to increase collaboration. The next guideline is personal accountability, which is the idea that each individual in a group must put forth their best effort for the team's overall success.[46] Personal accountability might be incorporated into video games by including an incentive system where individual players are rewarded with additional points for completing an objective or an action that improves the team's chances of success.[46] The final guideline, social skills, is the most important to consider when designing a collaborative game. An example of developing player social skills through a video game can be creating in-game situations where players have to assign roles, plan, and execute to solve the problem.[46] By following these guidelines, game makers can create gaming-environments which encourage collaboration and social interaction between players.

Applications of mobile devices

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Mobile devices are generally more accessible than their non-mobile counterparts, with about 41% of the world's population as per a survey from 2019 owning a mobile device.[47] This coupled with their relative ease of transport makes mobile devices usable in a large variety of settings which other computing devices would not function as well.[47] Because of this, mobile devices make videoconferencing and texting possible in a variety of settings which would not be accessible without such a device.[47]

The Chinese social media platform WeChat has is utilized to facilitate communication between patients and doctors.[48] WeChat is able to enhance healthcare interactions between patient and doctor by allowing direct communication of the patient's symptoms.[48]

Applications in social media

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Social media tools and platforms have expanded virtual communication amongst various generations. However, with older individuals being less comfortable with CSCW tools, it is difficult to design social platforms that account for both older and younger generational social needs.[49]

Often, these social systems focus key functionality and feature creation for younger demographics, causing issues in adaptability for older generations. In addition, with the lack of scalability for these features, the tools are not able to adapt to fit evolutional needs of generations as they age.[50] With the difficulty for older demographics to adopt these intergenerational virtual platforms, the risk of social isolation is increased in them.

While systems have been created specifically for older generations to communicate amongst one another, system design frameworks are not complex enough to lend to intergenerational communication.

Applications to ubiquitous computing

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Along the lines of a more collaborative modality is something called ubiquitous computing. Ubiquitous computing was first coined by Mark Weiser of Xerox PARC.[51] This was to describe the phenomenon of computing technologies becoming prevalent everywhere. A new language was created to observe both the dynamics of computers becoming available at mass scale and its effects on users in collaborative systems. Between the use of social commerce apps, the rise of social media, and the widespread availability of smart devices and the Internet, there is a growing area of research within CSCW that how come out of these three trends. These topics include ethnomethodology and conversation analysis (EMCA) within social media, ubiquitous computing, and instant message based social commerce.

Ethnomethodology and synchronicity

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In You Recommend I Buy: How and Why People Engage in Instant Messaging Based Social Commerce, researchers on this project analyzed twelve users of Chinese Instant Messenger (IM) social commerce platforms to study how social recommendation engines on IM commerce platforms result in a different user experience. The study was entirely on Chinese platforms, mainly WeChat. The research was conducted by a team composed of members from Stanford, Beijing, Boston, and Kyoto. The interviewing process took place in the winter of 2020 and was an entirely qualitative analysis, using just interviews. The goal of the interviews were to probe about how participants got involved in IM based social commerce, their experience on IM based social commerce, the reasons for and against IM based social commerce, and changes introduced by IM based social commerce to their lives. An IM-based service integrates directly with more intimate social experiences. Essentially, IM is real-time texting over a network. This can be both a synchronous or asynchronous activity. IM based social commerce makes the user shopping experience more accessible. In terms of CSCW, this is an example of ubiquitous computing. This creates a "jump out of the box" experience as described in the research because the IM based platform facilitates a change in user behavior and the overall experience on social commerce.[52] The benefit of this concept is that the app is leveraging personal relationships and real-life networks that can actually lead to a more meaningful customer experience, which is founded upon trust.

Embeddedness

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A second CSCW paper, Embeddedness and Sequentiality in Social Media, explores a new methodology for analyzing social media—another expression of ubiquitous computing in CSCW. This paper used ethnomethodology and conversation analysis (EMCA) as a framework to research Facebook users. In brief, ethnomethodology studies the everyday interactions of people and relates how this pertains to forming their outlook of the world. Conversational analysis delves into the structures of conversations so as to extract information about how people construct their experiences. The team behind this research, hailing from University of Nottingham and Stockholm University, recognized that "moment-by-moment, unfolding, real-time human action" was somewhat missing from the CSCW literature on social media.[53] The significance of this is they felt that by exploring EMCA, it could provide different insights on collaborative social network systems, as opposed to relying solely on recall.[53] Here is a formal definition for EMCA:

For EMCA, the activities of everyday life are structured in time—some things routinely happen before others. Fundamentally there is a 'sequentiality' to activity, something that has been vital for developing understanding of the orderly nature of talk and bodily interaction.[53]

In other words, EMCA pays attention to the sequence of events, so as to reveal some sort of underlying order about our behavior in our day-to-day interactions. In the bigger picture, this work reveals that time, as one of the dimensions to consider within collaborative systems design, matters. Another major factor would be distance. Does Distance Still Matter? Revisiting the CSCW Fundamentals on Distributed Collaboration is another research article that, as the title suggests, explores under what circumstances distance matters. Most notably, it mentions the "mutual knowledge problem."[54] This problem arises when a group in a distributed collaborative system experiences a breakdown in communication due to the fact that its members lack a shared understanding for the given context they are working in. According to the article, it matters that everyone is in alignment over the nature of what they are doing.

Co-located, parallel and sequential activities

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The solutions of unresolved issues in ubiquitous computing systems can be explored now that the observations of user experiences in social media, which are normally based on recollection, are no longer needed. Some of the unresolved questions include: "How does social media start being used, stop being used? When is it being used, and how is that usage ordered and integrated into other, parallel activities at the time?"[53]

Parallel activities refer to occurrences in co-located groupware and ubiquitous computing technologies like social media. Examining these sequential and parallel activities in user groups on social media networks enables the ability to "[manage] the experience of that everyday life."[53] An important takeaway from this paper on EMCA and sequentiality is that it reveals how the choices made by designers of social media apps ultimately mediates our end-user experience, for better or for worse. It reveals: "when content is posted and sequentially what is associated with it."[53]

Ubiquitous computing infrastructures

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On the topic of computing infrastructures, Democratizing Ubiquitous Computing – a Right for Locality presents a study from researchers at Lancaster University on ubiquitous computing ("ubicomp") to identify where there exists positive or negative effects on users and society at large.[55] The research specifically focuses on cities or urban areas as they are places where one can expect a lot of technological and social activities to take place. An apparent guiding principle to the research is that the goal of advancing any ubicomp technologies should be to maximize the amount of good to as many people in a society as possible. A key observation is made about the way in which these infrastructures come into being:

A ubiquitous computing infrastructure can play an important role in enabling and enhancing beneficial social processes as, unlike electricity, digital infrastructure enhances a society's cognitive power by its ability to connect people and information [39]. While infrastructure projects in the past had the idealistic notion to connect the urban realm and its communities of different ethnicity, wealth, and beliefs, Graham et al. [28] note the increasing fragmentation of the management and ownership of infrastructures.[55] This is because ubicomp has the potential to further disadvantage marginalized communities online.

The current disadvantage of ubiquitous computing infrastructures is that they do not best support urban development. Proposals to resolve these social issues include increased transparency about personal data collection as well as individual and community accountability about the data collection process in ubicomp infrastructure. Data at work: supporting sharing in science and engineering is one such paper that goes into greater depth about how to build better infrastructures that enable open data-sharing and thus, empower its users. What this article outlines is that in building better collaborative systems that advance science and society, we are, by effect, "promoting sharing behaviors" that will encourage greater cooperation and more effective outcomes.[56]

Essentially, ubiquitous computing will reflect society and the choices it makes will influence those computing systems that are put in place. Ubiquitous computing is huge to the field of CSCW because as the barriers between physical boundaries that separate us break down with the adoption of technology, our relationships to those locations is actually strengthened.[55] However, there remains few potential challenges when it comes to social collaboration and the workplace.

Challenges

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Social – technical gap

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The success of CSCW systems is often so contingent on the social context that it is difficult to generalize. Consequently, CSCW systems that are based on the design of successful ones may fail to be appropriated in other seemingly similar contexts for a variety of reasons that are nearly impossible to identify a priori.[3] CSCW researcher Mark Ackerman calls this "divide between what we know we must support socially and what we can support technically" the social-technical gap and describes CSCW's main research agenda to be "exploring, understanding, and hopefully ameliorating" this gap.[57]

It is important to analyze 'what we know we must support socially' for a few reasons. The way interaction takes place within an in-person setting is something that cannot be easily changed unlike the way technology is able to be manipulated to fit specific needs today. There are certain norms and standards lived up to within peoples' day to day lives, a certain part of those norms and attitudes carry over into the online world. The problem is mimicking daily communication styles and behavior into an online setting. Schmidt examines this concept within "Mind the Gap", he states "Cooperative work is a tricky phenomenon. We are all engaged in cooperative activities of various sorts in our everyday lives and routinely observe others working together around us. We are all experts from our everyday experience. And yet this quotidian insight can be utterly misleading when applied to the design of systems to support cooperative work".[58] Though in-person communication on a day-to-day basis is natural for most, it does not easily translate over into cooperative work. This highlights the need for adaptability within CSCW systems, Schmidt expands on the "crucial requirement of flexibility that arises from the changing needs of the cooperative work setting".[58] These all tie together to highlight the gaps within CSCW.

Leadership

[edit]

Generally, teams working in a CSCW environment need the same types of leadership as non-CSCW teams. However, research has shown that distributed CSCW teams may need more direction at the time the group is formed than traditional working groups, largely to promote cohesion and liking among people who may not have as many opportunities to interact in person, both before and after the formation of the working group.[59]

Adoption of groupware

[edit]
A group calendar allowing for collaboration of schedules

Groupware goes hand in hand with CSCW. The term refers to software that is designed to support activities of a group or organization over a network and includes email, conferencing tools, group calendars, workflow management tools, etc.[60]

While groupware enables geographically dispersed teams to achieve organizational goals and engage in cooperative work, there are also many challenges that accompany use of such systems. For instance, groupware often requires users to learn a new system, which users may perceive as creating more work for them without much benefit. If team members are not willing to learn and adopt groupware, it is highly difficult for the organization to develop the requisite critical mass for the groupware to be useful. Further, research has found that groupware requires careful implementation into a group setting, and product developers have not as yet been able to find the most optimal way to introduce such systems into organizational environments.[60]

On the technical side, networking issues with groupware often create challenges in using groupware for CSCW. While access to the Internet is becoming increasingly ubiquitous, geographically dispersed users still face challenges of differing network conditions. For instance, web conferencing can be quite challenging if some members have a very slow connection and others are able to utilize high speed connections.[60]

Intergenerational groups

[edit]

Adapting CSCW tools for intergenerational groups is a prevalent issue within all forms of CSCW. Different generations have different feelings towards technology as well as different ways to utilize technology. However, as technology has become integral to everyday tasks, it must be accessible to all generations of people. With cooperative work becoming increasingly important and diversified, virtual interaction between different generations is also expanding.[61] Given this, many fields that utilize CSCW tools require carefully designed frameworks to account for different generations.

Workplace teams

[edit]

One of the recurring challenges in CSCW environments is development of an infrastructure that can bridge cross-generational gaps in virtual teams.[62]

Many companies rely on communication and collaboration between intergenerational employees to be successful, and often this collaboration is performed using various software and technologies. These team-driven groupware platforms range from email and daily calendars to version control platforms, task management software, and more. These tools must be accessible to workplace teams virtually, with remote work becoming more commonplace.[63]

Ideally, system designs will accommodate all team members, but orienting older workers to new CSCW tools can often be difficult. This can cause problems in virtual teams due to the necessity of incorporating the wealth of knowledge and expertise that older workers bring to the table with the technological challenges of new virtual environments. Orienting and retraining older workers to effectively utilize new technology can often be difficult, as they generally have less experience than younger workers with learning such new technologies.

As older workers delay their retirement and re-enter the workforce, teams are becoming increasingly intergenerational, meaning that the creation of effective intergenerational CSCW frameworks for virtual environments is essential.[64]

Tools in CSCW

[edit]

Collaboration amongst peers has always been an integral aspect to getting something done. Working together not only eases the difficulty of the task at hand, but leads to more effective work that is accomplished.[65] As computers and technology become increasingly important in everyday lives, communication skills change as technology allows individuals to stay connected across many previous barriers. Barriers to communication might have been the end of the work day, being across the country or even slow applications that are more of a hindrance than an aid. With new collaborative tools that have been tried and tested, these previous barriers to communication have been shattered and replaced with new tools that help progress collaboration. Tools that have been integral in shaping computer supported cooperative work can be split into two major categories: communication and organization.

A screenshot showing the ability to set a reminder and also call using Slack, a tool in CSCW
  • Communication: The ability to communicate with others while working is a luxury that has increased the speed and accuracy at which tasks are accomplished. Individuals can also send pictures of code and issues through platforms like Microsoft Teams without anyone needing to change screen monitors. This particular change increased office productivity and communication by almost half.[4] The ability to send more specific information faster gave the employees the ability to get more done with also much less effort for themselves.[4] Tools like Microsoft Teams and Slack also allow people to collaborate with ease even if they are in different time zones or different geographical areas. This means that work is no longer tied to specific offices at a 9 to 5 job, but can be done anywhere because you have the ability to communicate with one or groups of people on a large scale.
  • Organization: Apps such as iCal and Reminders on the iPhone provide time-oriented structure and remind users of the tasks they must complete. Organization and communication go hand in hand with one another, as they help individuals better plan their day because apps warn them when two events overlap, a due date approaches, or whether there is time available for an event. There is reduced hassle to daily scheduling and group coordination.[66][67] Such apps usually tie into different electronic devices such as computers and tablets, therefore people receive reminders across multiple platforms. If the platform permits, individuals in teams can set reminders for other people.[66]

Departmental conflicts

[edit]

Cross-boundary breakdowns

[edit]

Cross-boundary breakdowns are when different departments of the same organization unintentionally harm other.[68] They may be caused by failures to coordinate activities across multiple departments, a form of articulation work.[68]

Hospitals may experience cross-boundary breakdowns during patient transfers.[68] When a patient is sent from the emergency department to the operation room, the inpatient access department (IPA) must normally be notified, allowing them to track the number and location of available ICU beds.[68] However, when the emergency department fails to notify the IPA, the IPA staff are later unable to find suitable beds for patients.[68]

Re-coordinating activities

[edit]

To restore useful communication between departments after a cross-boundary breakdown, organizations may perform re-coordinating activities.[68]

Hospitals may respond to cross-boundary breakdowns by explicitly ranking key resources or assigning "integrator" roles to multiple staff members across different departments.[68]

Challenges in research

[edit]

Differing meanings

[edit]

In the CSCW field, researchers rely on a variety of sources that include journals and research schools of thought. These different sources may lead to disagreement and confusion, as there are terms in the field that can be used in different contexts ("user", "implementation", etc.) User requirements change over time and are often not clear to participants due to their evolving nature and the fact that requirements are always in flux.[69]

Identifying user needs

[edit]

CSCW researchers often have difficulty deciding which set(s) of tools will benefit a particular group because of the nuances within organizations.[70] This is exacerbated by the fact that it is challenging to accurately identify user/group/organization needs and requirements, since such needs and requirements inevitably change through the introduction of the system itself. When researchers study requirements multiple times, the requirements themselves often change and evolve once the researchers have completed a particular iteration.

Evaluation and measurement

[edit]

The range of disciplinary approaches leveraged in implementing CSCW systems makes CSCW difficult to evaluate, measure, and generalize to multiple populations. Because researchers evaluating CSCW systems often bypass quantitative data in favor of naturalistic inquiry, results can be largely subjective due to the complexity and nuances of organizations themselves. Possibly as a result of the debate between qualitative and quantitative researchers, three evaluation approaches have emerged in the literature examining CSCW systems. However, each approach faces its own unique challenges and weaknesses:[71]

Evaluation approach Usage Weakness
Methodology-oriented frameworks Explain the methods of inquiry available to CSCW researchers Not providing guidance for selecting the best method for a particular research question or population
Conceptual frameworks Provide guidelines for determining factors that a researcher should consider and evaluate through CSCW research Fail to link conceptual constructs with methodological approaches. Thus, while researchers may know what factors are important to their inquiry, they may have difficulty understanding which methodologies will result in the most informative findings[67]
Concept-oriented frameworks Provide specific advice for studying isolated aspects of CSCW Lack guidance as to how specific areas of study can be combined to form more comprehensive insight

Diversity, equity, and inclusion

[edit]

Gender

[edit]

In computer-supported cooperative work, there are small psychological differences between how men and women approach CSCW programs.[72] This can lead to unintentionally biased systems, due to the majority of software being designed and tested by men. As well, in systems where societal gender differences are not accounted for and countered, men tend to overrepresent women in these online spaces.[73] This can lead to women feeling potentially alienated and unfairly targeted by CSCW programs.

In recent years, more studies have been conducted on how men and women interact with each other using CSCW systems. Findings do not indicate that men and women have performance difference when performing CSCW tasks, but rather that each gender approaches and interacts with software and performs CSCW tasks differently. In most findings, men were more likely to explore potential choices and willing to take risks compared to women.[73] In group tasks, women in general were more conservative in voicing their opinions and suggestions on tasks when paired with a male, but inversely were very communicative when paired with another woman. As well, men are found to be more likely to take control of group activities and teamwork, even from a young age,[72] leading to further ostracizing of women speaking up in CSCW group work. Additionally, in CSCW message boards, men on average posted more messages and engaged more frequently than their female counterparts.[74]

Increasing female participation

[edit]

The dynamic of women in the workforce not participating as much is less of a CSCW problem and is prevalent in all workspaces, but software can still be designed to increase female participation in CSCW. In software design, women are more likely to be involved if software is designed to center communication and cooperation. This is one possible method to increasing female participation, and it does not address why CSCW has lower female participation in the first place.

Strategies for getting females more interested in STEM

In a study, women generally rated themselves as being poor at understanding technology, having difficulty at using mobile programs, and disliked using CSCW software. However, when asked these same questions about specific software in general, they rated themselves just as strongly as the men in the study did.[75] This lack of confidence in software as a whole impacts women's ability to efficiently and effectively use online programs compared to men, and accounts for some of the difficulties women face in using CSCW software.[75]

Despite being an active area of research since the 1990s,[76] many developers often do not take gender differences into account when designing their CSCW systems.[76] These issues compound on top of the cultural problems mentioned previously, and lead to further difficulties for women in CSCW. By enabling developers to be more aware of the differences and difficulties facing women in CSCW design, women can be more effective users of CSCW systems through sharing and voicing opinions.

Conferences

[edit]

Since 2010, the Association for Computing Machinery (ACM) has hosted a yearly conference on CSCW, "The ACM Conference on Computer Supported Cooperative Work", or CSCW for short. The conference is sponsored by the SIGCHI special interest group. From 1986 to 2010, it was held biannually.[77] The conference is currently held in October or November and features research in the design and use of technologies that affect organizational and group work. With the rapidly increasing development of new devices that allow collaboration from different locations and contexts, CSCW seeks to bring together researchers from across academia and industry to discuss the many facets of virtual collaboration from both social and technical perspectives.

Internationally, the Institute of Electrical and Electronics Engineers (IEEE) sponsors the International Conference on Computer Supported Work in Design, which takes place yearly.[78] In addition, the European Society for Socially Embedded Technologies sponsors the European Conference on Computer Supported Cooperative Work, which has been held every two years since 1989.[79] CSCW panels are a regular component of conferences of the adjacent field of science and technology studies.

See also

[edit]

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  55. ^ a b c Weise, Sebastian; Hardy, John; Agarwal, Pragya; Coulton, Paul; Friday, Adrian; Chiasson, Mike (2012-09-05). "Democratizing ubiquitous computing". Proceedings of the 2012 ACM Conference on Ubiquitous Computing. UbiComp '12. Pittsburgh, Pennsylvania: Association for Computing Machinery. pp. 521–530. doi:10.1145/2370216.2370293. ISBN 978-1-4503-1224-0. S2CID 13640738.
  56. ^ Birnholtz, Jeremy P.; Bietz, Matthew J. (2003-11-09). "Data at work". Proceedings of the 2003 international ACM SIGGROUP conference on Supporting group work. GROUP '03. Sanibel Island, Florida: Association for Computing Machinery. pp. 339–348. doi:10.1145/958160.958215. ISBN 978-1-58113-693-7. S2CID 8748434.
  57. ^ Ackerman, M. (2000). "The Intellectual Challenge of CSCW: The gap between social requirements and technical feasibility". Human-Computer Interaction. 15 (2): 179–203. CiteSeerX 10.1.1.4.9910. doi:10.1207/S15327051HCI1523_5. S2CID 2676709.
  58. ^ a b Schmidt, K.; Simone, C. (2000). "Mind the Gap! Towards a Unified View of CSCW". COOP. S2CID 16452016.
  59. ^ Thompson, L.F; Coovert, M.D (2006). Bowers, C.; Salas, E.; Jentsch, F. (eds.). "Understanding and developing virtual computer-supported cooperative work teams". Creating Hi-tech Teams: 213–241.
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Further reading

[edit]
Most cited papers

This list, the CSCW Handbook Papers, is the result of a citation graph analysis of the CSCW Conference.[1][2] It was established in 2006 and reviewed by the CSCW community. This list only contains papers published in one conference; papers published at other venues have also had significant impact on the CSCW community. The "CSCW handbook"[2] papers were chosen as the overall most cited within the CSCW conference ... It led to a list of 47 papers, corresponding to about 11% of all papers.

  1. Dourish, P.; Bellotti, V. (1992). "Awareness and coordination in shared workspaces". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 107–114.
  2. Grudin, J. (1988). "Why CSCW applications fail: problems in the design and evaluation of organization of organizational interfaces". Proceedings of the 1988 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 85–93.
  3. Root, R.W. (1988). "Design of a multi-media vehicle for social browsing". Proceedings of the 1988 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 25–38.
  4. Patterson, J.F.; Hill, R.D.; Rohall, S.L.; Meeks, S.W. (1990). "Rendezvous: an architecture for synchronous multi-user applications". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 317–328.
  5. Greenberg, S.; Marwood, D. (1994). "Real time groupware as a distributed system: concurrency control and its effect on the interface". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 207–217.
  6. Nardi, B.A.; Whittaker, S.; Bradner, E. (2000). "Interaction and outeraction: instant messaging in action". Proceedings of the 2000 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 79–88.
  7. Hughes, J.A.; Randall, D.; Shapiro, D. (1992). "Faltering from ethnography to design". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 115–122.
  8. Tang, J.C.; Isaacs, E.A.; Rua, M. (1994). "Supporting distributed groups with a Montage of lightweight interactions". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 23–34.
  9. Neuwirth, C.M.; Kaufer, D.S.; Chandhok, R.; Morris, J.H. (1990). "Issues in the design of computer support for co-authoring and commenting". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 183–195.
  10. Crowley, T.; Milazzo, P.; Baker, E.; Forsdick, H.; Tomlinson, R. (1990). "MMConf: an infrastructure for building shared multimedia applications". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 329–342.
  11. Roseman, M.; Greenberg, S. (1992). "GROUPKIT: a groupware toolkit for building real-time conferencing applications". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 43–50.
  12. Shen, H.H.; Dewan, P. (1992). "Access control for collaborative environments". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 51–58.
  13. Gaver, W.W. (1992). "The affordances of media spaces for collaboration". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 17–24.
  14. Orlikowski, W.J. (1992). "Learning from Notes: organizational issues in groupware implementation". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 362–369.
  15. Sun, C.; Ellis, C. (1998). "Operational transformation in real-time group editors: issues, algorithms, and achievements". Proceedings of the 1998 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 59–68.
  16. Bly, S.A. (1988). "A use of drawing surfaces in different collaborative settings". Proceedings of the 1988 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 250–256.
  17. Leland, M.D.P.; Fish, R.S.; Kraut, R.E. (1988). "Collaborative document production using quilt". Proceedings of the 1988 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 206–215.
  18. Conklin, J.; Begeman, M.L. (1988). "gIBIS: a hypertext tool for exploratory policy discussion". ACM Transactions on Information Systems. 6 (4): 303–331. doi:10.1145/58566.59297. S2CID 2609461.
  19. Bentley, R.; Hughes, J.A.; Randall, D.; Rodden, T.; Sawyer, P.; Shapiro, D.; Sommerville, I. (1992). "Ethnographically-informed systems design for air traffic control". Proceedings of the 1992 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 123–129.
  20. Mantei, M. (1988). "Capturing the capture concepts: a case study in the design of computer-supported meeting environments". Proceedings of the 1988 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 257–270.
  21. Lantz, K.A. (1986). "An experiment in integrated multimedia conferencing". Proceedings of the 1986 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 267–275.
  22. Harrison, S.; Dourish, P. (1996). "Re-place-ing space: the roles of place and space in collaborative systems". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 67–76.
  23. Roseman, M.; Greenberg, S. (1996). "TeamRooms: network places for collaboration". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 325–333.
  24. Ishii, H. (1990). "TeamWorkStation: towards a seamless shared workspace". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 13–26.
  25. Ressel, M.; Nitsche-ruhland, D.; Gunzenhäuser, R. (1996). "An integrating, transformation-oriented approach to concurrency control and undo in group editors". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 288–297.
  26. Edwards, W.K. (1996). "Policies and roles in collaborative applications". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 11–20.
  27. Bellotti, V.; Bly, S. (1996). "Walking away from the desktop computer: distributed collaboration and mobility in a product design team". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 209–218.
  28. Ackerman, M.S. (1998). "Augmenting Organizational Memory: A Field Study of Answer Garden". ACM Transactions on Information Systems. 16 (3): 203–224. CiteSeerX 10.1.1.12.589. doi:10.1145/290159.290160. S2CID 15780647.
  29. Abbott, K.R.; Sarin, S.K. (1994). "Experiences with workflow management: issues for the next generation". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 113–120.
  30. Resnick, P.; Iacovou, N.; Suchak, M.; Bergstrom, P.; Riedl, J. (1994). "GroupLens: an open architecture for collaborative filtering of netnews". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 175–186.
  31. Prakash, A.; Shim, H.S. (1994). "DistView: support for building efficient collaborative applications using replicated objects". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 153–164.
  32. Streitz, N.A.; Geißler, J.; Haake, J.M.; Hol, J. (1994). "DOLPHIN: integrated meeting support across local and remote desktop environments and LiveBoards". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 345–358.
  33. Foster, G.; Stefik, M. (1986). "Cognoter: theory and practice of a colab-orative tool". Proceedings of the 1986 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 7–15.
  34. Shen, C.; Lesh, N.B.; Vernier, F.; Forlines, C.; Frost, J. (2002). "Sharing and building digital group histories". Proceedings of the 2002 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 324–333.
  35. Sohlenkamp, M.; Chwelos, G. (1994). "Integrating communication, cooperation, and awareness: the DIVA virtual office environment". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 331–343.
  36. Olson, J.S.; Teasley, S. (1996). "Groupware in the wild: lessons learned from a year of virtual collocation". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 419–427.
  37. Reder, S.; Schwab, R.G. (1990). "The temporal structure of cooperative activity". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 303–316.
  38. Fish, R.S.; Kraut, R.E.; Chalfonte, B.L. (1990). "The VideoWindow system in informal communication". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 1–11.
  39. Haake, J.M.; Wilson, B. (1992). "Supporting collaborative writing of hyperdocuments in SEPIA". Proceedings of the 1992 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 138–146.
  40. Hudson, S.E.; Smith, I. (1996). "Techniques for addressing fundamental privacy and disruption tradeoffs in awareness support systems". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 248–257.
  41. MacKay, W.E. (1990). "Patterns of sharing customizable software". Proceedings of the 1990 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 209–221.
  42. Trigg, R.H.; Suchman, L.A.; Halasz, F.G. (1986). "Supporting collaboration in notecards". Proceedings of the 1986 ACM conference on Computer-supported cooperative work. New York: ACM Press. pp. 153–162.
  43. Patterson, J.F.; Day, M.; Kucan, J. (1996). "Notification servers for synchronous groupware". Proceedings of the 1996 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 122–129.
  44. Myers, B.A.; Stiel, H.; Gargiulo, R. (1998). "Collaboration using multiple PDAs connected to a PC". Proceedings of the 1998 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 285–294.
  45. Ackerman, M.S.; Halverson, C. (1998). "Considering an organization's memory". Proceedings of the 1998 ACM conference on Computer supported cooperative work. New York, NY: ACM Press. pp. 39–48.
  46. Teasley, S.; Covi, L.; Krishnan, M.S.; Olson, J.S. (2000). "How does radical collocation help a team succeed?". Proceedings of the 2000 ACM conference on Computer supported cooperative work. New York, NY: ACM Press. pp. 339–346.
  47. Kuzuoka, H.; Kosuge, T.; Tanaka, M. (1994). "GestureCam: a video communication system for sympathetic remote collaboration". Proceedings of the 1994 ACM conference on Computer supported cooperative work. New York: ACM Press. pp. 35–43.
[edit]
  1. ^ CSCW Handbook Papers
  2. ^ a b Jacovi, M.; Soroka, V.; Gilboa-freedman, G.; Ur, S.; Shahar, E.; Marmasse, N. (2006). "The chasms of CSCW: a citation graph analysis of the CSCW conference". Proceedings of the 2006 20th anniversary conference on Computer supported cooperative work. ACM Press New York, NY. pp. 289–298.