EP1221093A2 - System and method for supporting group interaction (gia) in hypermedial information rooms - Google Patents

Abstract

The invention relates to a group interaction (GIA) system and a method by means of which hypermedial information systems are enlarged by co-ordinated functions in such a way that several platforms are involved, whereby said functions serve for supporting human interaction. According to the inventive system and method, system components are coupled in a stable and network-transparent manner by means of internet services for instance. The system components are distributed in a computer and/or to different computers in an internet. The system components are coupled by means of events. The stability and flexibility of the entire system is tremendously increased by virtue of the asynchronous coupling of the components.

Description

description

System and method to support group interaction (GIA) in hypermedia information spaces

The invention relates to a system and method for supporting the

Group interaction (GIA) in hypermedia information rooms for clients and service providers (servers) according to the preamble of claims 1 and 10.

The Internet has become the standard network for distributed applications. A major problem in the development of distributed, complex applications in special application contexts is the dependency of the system architecture and the

Implementation of the respective network structures.

The Internet protocols in the context of the Word Wide Web (WWW) essentially support the representation, storage, distribution and display of hypermedia information in a cross-platform form. The invention is based on the object of a system and a method which expand the existing hypermedia information systems for clients and servers, for example web-based information systems, by coordinated functions to support human interaction. The invention is for the system by the characteristic features of

Claim lund for the method described by the characterizing features of claim 10. Advantageous further developments and refinements are specified in the subclaims.

The GIA system is used in the following as a reference implementation, i.e. shown in a possible version of the GIA architecture. The decisions for specific implementation variants, e.g. WWW as a hypermedia system or the version of the user interface shown do not necessarily result from the GIA architecture, but the currently most advantageous variants are selected in accordance with the prior art.

The GIA system has the advantage that hypermedia information systems are expanded to include coordinated functions to support human interaction across platforms and that a stable and network-transparent coupling of system components via Internet services is achieved. The system modules are distributed on different computers in an Internet and in the computer in different process rooms. The system blocks are linked via events. Both synchronous and asynchronous coupling are supported. The asynchronous coupling of the blocks significantly increases the stability and flexibility of the overall system. In contrast to existing approaches (RMI, SUN / CORBA), transmission is advantageously not restricted to a specific communication protocol, but rather any existing Internet protocols (sockets, RMI, NNTP, SMTP etc.) and new so-called distributed event system protocols Coupling used. The GIA architecture supports the transparent, simultaneous use of several protocols (multiprotocol coupling). In addition, an automatic selection of adequate coupling protocols is provided (auto protocol selection). The coupling protocols are independent of hardware and software platforms. The GIA system according to the invention is shown below using the example of a website. The information and control processes of the WWW-based group interaction are explained in more detail as exemplary embodiments on the basis of activity diagrams with reference to schematic diagrams.

The GIA system architecture is shown in FIG.

Fig. 2 shows an activity diagram "registration".

3 shows an activity diagram “URL change”

Fig. 4 shows an activity diagram "start of following".

5 shows an activity diagram "URL change when following"

The subject-specific English expressions, which are also familiar in the German language, are used to describe the invention.

The present GIA system consists on the one hand of new types of CSCW (Computer Supported Cooperative Work) services, e.g. Service for user and group perception (awareness) and services to support cooperative navigation in the information space (cooperative navigation). Five coordinated CSCW functions are currently implemented in the GIA system:

1. User awareness (awareness): While the web users move around on the web page, they are aware of other users and supervisors who are in the same place or subordinate places. The web users are visualized in a room plan metaphor. The perception of other users conveys the

Liveness of the system and thus increases its attractiveness. Perception is too a prerequisite for getting to know other users and building communities.

2. Local chat: The web users can communicate with the other users of a page in the GIA system. If a user changes the page, his local chat group can also be changed automatically.

3. Location discussion forums: An asynchronous discussion forum can be assigned to the locations. When entering the site, the user can activate the forum and add comments to the information or reply to existing comments. This also supports asynchronous human communication. Similar to the local chat, the forum can be adapted when changing pages.

4. Cooperative navigation: Users can connect their browsers. In this way, individual instructions or interactive "guided tours" can be realized.

5. Known chat: It is possible to set up chat groups that exist regardless of the changing locations of the users. So stable and location independent

Communication channels are established.

The building blocks of the client / server architecture are divided into external applications and internal applications. External applications are commercially available systems that can only be controlled via standard interfaces and whose user interface cannot be changed in general. Internal applications are available in the source code and can therefore be better controlled. In addition, their user interface can be adapted to the needs of the application environment.

1, the server 2 is divided into the GIA server 5 for internal applications and external server applications 4.

The GIA server 5 implements, via appropriate managers, all system functions that are necessary for the server, but which are not or only insufficiently covered by server-side CSCW (Computer Supported Cooperative Work) applications that are already commercially available. Components of the GIA server are for example a GIA main manager, group manager, structure manager, notification manager and external application adapter 3b.

External applications include all applications that support GIA functions that can be covered by commercially available systems. These include the servers for Internet protocols, such as the EMAIL, NNTP, IRC and HTTP servers, as well as databases and the file system of the server operating system.

Client 1 is divided into GIA clients 6 for internal applications, GIA Internet protocol clients 8 and external client applications 7.

The GIA client 6 implements all system functions that are necessary for the internal applications, but are not or only insufficiently covered by client-side CSCW systems that are already commercially available. Components of the GIA client 6 are, for example, a GIA main client, RMV (Room Map View) client, notification client and external application adapter 3c.

The GIA Internet protocol clients 8 implement client-side user interfaces for applications that consist of standardized Internet protocols. EMAIL, NNTP and the IRC client belong to this category.

External client applications 7 include all applications to support the GIA functions that are covered by commercially available systems. These include, for example, WWW browsers.

The connections between the blocks are the well-known Internet protocols, e.g. SMTP, POP, NNTP, IRC and HTTP and, on the other hand, a newly developed connection system for coupling GIA modules, a so-called distributed event system DES (Distributed Event System).

The GIA server modules 5 are server-side applications that are present in the source code and thus interact in a particularly coordinated manner. The functions of the GIA Servers are implemented by managers who run within server programs.

The GIA main manager is of central importance in the GIA architecture. It manages a corresponding session data structure for each GIA client logged on to the system. If the communication with the managers takes place via a central point, then the main manager for the GIA clients is also the interface to all other managers and for all managers the interface to the GIA clients. The GIA main manager offers other components session-specific events (registration, deregistration, change of location). The group manager implements the GIA functions for user grouping. Users who interact in the structured information spaces are grouped by the group manager based on their interactions with the GIA system. The resulting user groups are managed dynamically by the group manager based on modifiable grouping metrics. Clients and other servers can query the groups and their members from the group manager.

The structure manager implements functions for structuring the information space. Different structured information sources (file system, databases etc.) are integrated via the assigned adapters 3b. The structure information is kept dynamic and can be queried by the clients and other servers.

The Notification Manager implements functions for reacting to changes in the information room or the GIA system itself. It accepts inquiries that contain descriptions of changes in the state of the information room and independently triggers notification events when changes occur.

The external server applications 4 are not in the source code and therefore cannot be queried or controlled directly. External server applications 4 are server-side applications that are commercially available and are integrated into the GIA system via adapter 3 a. The adapter 3 a connect the external

Server applications with the GIA main manager and the notification manager by implementing functions for control (actuator) and query (sensor) from external applications. The adapters couple the application-specific details of the interaction with external applications. For example, the NNTP adapter interacts with applications provided by the NNTP protocol and converts internal requests into NNTP requests and NNTP responses into internal results.

The EMAIL server manages asynchronous user-addressed electronic messages. Examples of implementations are servers that are based on the Internet protocols SMTP and POP. The NNTP server manages asynchronous content-related hierarchies of electronic messages. The message hierarchies are in so-called

Discussion forums organized. The exchange of messages between client and server is based on the Internet protocol NNTP.

The IRC server manages synchronous electronic messages that are distributed via so-called channels based on the Internet protocol IRC. The HTTP server manages hypermedia multimedia data. The data are e.g. represented in the HTML standard and are exchanged via the HTTP protocol.

The GIA client building blocks 6 are client-side applications that are available in the source code and can therefore work together in a particularly coordinated manner.

The main GIA client has two main functions. On the one hand, it represents the main connection to the GIA server and thus makes events of the server available to internal clients. On the other hand, he coordinates the CSCW services through interaction between the service-specific client modules and the adapters 3c, 3d.

The RMV client represents the position of a user in the information room on the basis of a room plan metaphor. The current position is represented as a corridor, the information rooms that can be reached from the current point of view by rooms in the room plan that are accessible from the corridor. The current position shows the user and all other users who are in the same information room. The same applies to the subspaces where the respective users present are visualized. The notification client enables the user of the GIA system to be notified of changes in the information space. For example, when a new message arrives in a forum of the NNTP server, an email is sent to the user.

The following GIA Internet protocol clients 8 are used, for example, in the GIA system.

An EMAIL client for composing, sending and receiving user-addressed electronic messages and sending them based on existing Internet standards.

An NNTP client for composing, sending and receiving content-related electronic messages in the context of so-called discussion forums of NNTP servers. The exchange of messages between client and server is based on the Internet protocol NNTP. An IRC client for composing, sending and receiving synchronous electronic messages that are exchanged via so-called channels based on the Internet protocol IRC.

EMAIL, NNTP and IRC clients are available in the source code and can be accessed and queried directly by the GIA client.

The external client applications 7 are not in the source code and therefore cannot be queried or controlled directly. The external client modules are client-side applications that are commercially available and integrated into the system via the 3d adapter. The adapter 3d implements functions for control (actuator) and query (sensor) of external applications. The adapter couples the application-specific details of the interaction with external applications. For example, the HTTP adapter interacts with browsers that represent the current section of the information space. The actuator of the adapter initiates the loading of new pages by the GIA system and the sensor forwards page changes by the user to the GIA system. For example, the HTTP client allows the loading of hypermedia data via the HTTP protocol and the display of the HTML data on the client computer. In the following, exemplary information and control processes of the components of the GIA system are described. The standardized interactions based on Internet protocols (SMTP, POP, NNTP, IRC, HTTP) are not specified, since these can be found in the corresponding RFC (Request For Comment) documents.

The blocks are linked via the distributed event system DES. The processes in the system are shown below with activity diagrams. In these diagrams, activities are shown as rounded rectangles. The horizontal arrangement of these activities results from the "place" at which they take place (here the corresponding software components). The vertical arrangement reflects the chronological sequence. The activities are linked by arrows on which the relevant event class is noted.

Exemplary embodiment: registration (FIG. 2)

If the GIA user starts the registration process, for example, the GIA client will ask for his user information. Provided with this information, the GIA client sends an event El (NewSessionEvent) to the GIA main manager. Upon receipt of the NewSessionEvent, the GIA main manager creates a new session class. Another event E2 (NewSessionConfirmationEvent) is then sent to the GIA client, indicating that the new session was successfully created. In addition, this event also contains the session ID (identification) of the GIA client, which he must send to the session server for identification with every further request. Since the group manager has registered for the creation of new sessions, he is also informed of this by means of another event E3 (SessionlnitiatedEvents). If the GIA client receives the NewSessionConfirmationEvent, the registration process is completed. It sets the user interface to active. After receiving the Session InitiatedEvent, the group manager enters the SessionData object transferred in it into its session table and into the corresponding group object. Now the group manager only has to send another event E4 (GroupChangeEvent) to the GIA client. Upon receipt of the GroupChangeEvent, the GIA client can update their location map and location chat.

Exemplary embodiment: URL change (FIG. 3) If the GIA user loads a new page in the HTTP client, the GIA client registers this via the corresponding adapter. This triggers an event E5 (URLChangeEvent) within the main GIA client for which the main GIA manager has registered. Upon receipt of the URLChangeEvent by the GIA main manager, he updates the corresponding session object. Since the group manager has registered for changing URLs, it receives another event E6 (URLUpdateEvent). If the group manager receives a URLChangeEvent, it removes the corresponding SessionData object from the participant list of the abandoned group and enters it in the participant list of the new group. This triggers another event E7 (GroupChangeEvent), which is sent to the GIA client via the GIA main manager.

Upon receipt of the GroupChangeEvent, the GIA client can update their location map and location chat.

Exemplary embodiment: consequences (Fig. 4)

At the beginning of the following, a "follow" client (client 1) selects its "lead" client (client 2) and activates the follow mode (e.g. by selecting from a pop-up menu). This triggers an event E8 (StartFoUowingRequestEvent), which communicates this to the GIA main manager. The GIA main manager responds to this StartFoUowingRequestEvent by adding the session object from client 1 to the "follow-up list" in the session object from client 2 and the "leadership reference" in the session object from client 1 sets client 2's session object. He also sends another event E9 (FollowingStatusEvent) to client 1 and client 2. Client 2 is informed about his new "following" by this FollowingStatusEvent.

Depending on the FollowingStatusEvent, client 1 is informed of the successful or failed follow-up.

Claims

Patent claims

1. Group interaction (GIA) system in hypermedia information spaces for clients and service providers (servers), which are distributed in a computer in different process address spaces and on several computers in a network (Internet), characterized in that the GIA system consists of client (1) and

Server (2) modules for external and internal computer applications and network connections between external and/or internal client and server modules, that the server modules

(2) are divided into the GIA server (5) for internal applications and external server applications (4), and the client modules (1) are divided into the GIA client (6) for internal ones

Applications, external client applications (7) and Internet protocol clients (8), and that Internet protocols and/or distributed event system (DES) protocols form the network connections between the client and server building blocks.

. Group interaction system according to claim 1, characterized in that the internal GIA server (5) contains managers that implement the functions of the GIA server, and that the GIA server has a main manager, a group manager, a structure manager , and contains a notification manager.

3. Group interaction system according to claim 1, characterized in that the external server applications (4) are connected to the main manager and notification manager via adapters (3a).

4. Group interaction system according to claim 2, characterized in that the structure manager is connected to external information sources via adapter (3b).

5. Group interaction system according to one of the preceding claims, characterized in that the modules for external server applications (4) are constructed from an EMAIL server, an NNTP server, an IRC server, an HTTP server.

6. Group interaction system according to claim 1, characterized in that the GIA client (6) consists of a GIA main client, an RMV client and a notification client.

7. Group interaction system according to claim 1, characterized in that the Internet protocol clients include an EMAIL client, an NNTP client and an IRC client.

8. Group interaction system according to claim 1, characterized in that a WWW browser is installed as an external client application (7).

9. Group interaction system according to claim 6 and 8, characterized in that an adapter (3d) connects the external client applications (7) to the GIA main client.

10. Method for group interaction (GIA) in hypermedia information spaces for clients and service providers (servers), characterized in that in a GIA system according to the preceding claims, the client (1) and server (2) modules for external and internal computer applications via network connections between the client and server, and that the network connections via Internet protocols and distributed

Event system (DES) protocols are established between client and server building blocks in such a way that events of the distributed external and internal computer applications are coupled.

11. Group interaction method according to claim 10, characterized in that the distributed event system (DES) protocols are coupled synchronously or asynchronously.

12. Group interaction method according to one of the preceding claims, characterized in that several distributed computer applications are coupled to the distributed event system (DES) protocols regardless of network restrictions (multi-protocol coupling).

13. Group interaction method according to one of the preceding claims, characterized in that the managers of the GIA server (5) and / or the GIA clients (6) are coupled to the distributed event system (DES) protocols.

14. Group interaction method according to one of the preceding claims, characterized in that external server applications (4) are coupled to the managers of the GIA server (5) via adapters (3a) using the distributed event system (DES) protocols.

15. Group interaction method according to one of the preceding claims, characterized in that Internet protocol client applications (8) are coupled to the GIA client (6) using the distributed event system (DES) protocols.

16. Group interaction method according to one of the preceding claims, characterized in that with the distributed event system (DES) protocols, external client applications (7) via the adapter (3d) with the GIA client

(6) can be coupled.

17. Group interaction method according to one of the preceding claims, characterized in that with the GIA main client on the one hand

Main connection to the GIA server is established and events from the server are made available to the GIA client, and on the other hand, with the GIA main client, the coordination of CSCW services through interaction with the service-specific clients and the adapters (3c, 3d) is carried out.

18. Group interaction method according to one of the preceding claims, characterized in that the RMV client is used to represent the position of a user in the information space based on a spatial plan metaphor, such that the current position is represented as a corridor and the information spaces accessible from the current position are represented by the Rooms accessible from the hallway

Room plan are displayed, and that all other users who are in the same information space are displayed at the user's current position.

19. Group interaction method according to claim 18, characterized in that the RMV client is used to display the position of users of subspaces in which the users present are visualized.

20. Group interaction method according to one of the preceding claims, characterized in that functions for reacting to changes in the information space or the GIA system itself are implemented with the notification manager, that requests are received with the notification manager, the descriptions of State changes in the information space are included, and that with the notification manager

When requested changes occur, notification events are triggered independently.

21. Group interaction method according to one of the preceding claims, characterized in that the notification client will notify users of the GIA system about changes in the information space.

22. Group interaction method according to claim 21, characterized in that an email is sent to the user with the notification client when a new message is received in a forum of the NNTP server.

23. Group interaction method according to one of the preceding claims, characterized in that the application-specific interactions with external applications (4, 7, 8) are carried out with the adapters (3a, 3b, 3c, 3d).

Actuators and sensors are coupled.

24. Group interaction method according to claim 23, characterized in that the adapter (3d) interacts with browsers that represent the current section of the information space in such a way that the actuator of the adapter triggers the loading of new pages by the GIA system and the sensor forwards page changes by the user to the GIA system.