Electrical computers and digital processing systems: multicomput – Computer-to-computer protocol implementing – Computer-to-computer data streaming
Reexamination Certificate
1998-04-15
2002-09-17
Courtenay, III, St. John (Department: 2151)
Electrical computers and digital processing systems: multicomput
Computer-to-computer protocol implementing
Computer-to-computer data streaming
Reexamination Certificate
active
06453356
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates generally to information systems, and more particularly, to a system and method for exchanging data among dissimilar applications.
BACKGROUND OF THE INVENTION
A number of proposed solutions have been advanced to address the problem of effecting the communication of data between computer system platforms and applications developed using distinctly different technologies. The increased reliance on distributed data processing systems and architectures, such as those employed to support Internet and Electronic Data Interchange (EDI) activities for example, has created a keenly felt need for improved methods of transporting vast amounts of data of various types and formats between applications having dissimilar interface characteristics.
In an attempt to address the problem of transporting dissimilar types of data between dissimilar systems and applications, various data interchange products and approaches have been developed. A traditional approach of electronically linking a number of disparate systems together involves the creation of custom gateways or interface systems. A typical custom gateway is created to solve a narrowly focused interface problem, such as permitting systems #
1
and #
2
to exchange data of types ‘A’ and ‘B’ produced by systems #
1
and #
2
, respectively. Such specialized gateways are generally not intended nor designed to accommodate data interchange between a large number of disparate systems and applications. It is understood in the art that modifying an existing custom gateway to address a new and different interface problem is generally unproductive and costly, given the inherent limitations of the original gateway design.
Various information technology standards have been advanced in an attempt to address these and other data interchange problems experienced within a distributed data processing and communications environment. One such standard, referred to in the art as CORBA (Common Object Request Broker), has received much recent attention, as it would appear to solve many of these problems. A critical review of the CORBA approach, however, reveals that CORBA is not designed to act as a data transport mechanism. Rather, CORBA is primarily designed to pass control methods over TCP/IP. The strength of CORBA is its ability to use C++ methods over a network. CORBA requires that all applications must be object oriented, which precludes inclusion of a substantial number of existing applications developed using structured programming techniques. Moreover, although CORBA is referred to as a “standard,” there are several product implementations of CORBA which are not compatible, and as such, are incapable of communicating with one another.
Other technologies, such as transaction monitors, have been developed primarily to control complex transactions between multiple applications in a distributed processing environment. Such transaction monitors typically interface applications through rigorous transaction rules applied through defined IDL (Interface Definition Language) interfaces across IPC (Inter Process Communication) methods. A typical transaction monitor has a complex structure that must be conformed to, and is complicated to use and maintain. If any one of the individual transactions that make up a transaction set fails, the entire complex transaction must be backed out, rather than the single failed transaction. Transaction monitors are generally optimized for transaction control, and not for effecting data interchange.
Fourth and fifth generation languages, termed 4GL and 5GL, would appear to offer a partial solution to the data interchange problem. These and other similar languages, such as those used to construct “business objects,” are optimized around the construction of applications and user interfaces for the primary purpose of providing powerful querying and reporting tools. The objects created by such languages typically define access paths to data residing in databases. The objects can be combined in various ways to create complex queries and for building powerful report generators. Fourth and fifth generation languages are not well suited for transporting vast amounts of data from one application to one or more other applications in a reliable and efficient manner. Although business objects constructed using 4GL and 5GL techniques do carry with them a certain amount of data, this data is typically data resulting from a query that is transported with an object definition for the purpose of performing additional analysis on the data.
There exists a keenly felt need for a data exchange system and methodology that is capable of exchanging data of varying size, content, and format between dissimilar systems and applications. There exists a further need for such a system and methodology that is independent of any current or future technology. The present invention fulfills these and other needs.
SUMMARY OF THE INVENTION
The present invention is directed to a system and method for exchanging data between two or more applications. The data exchange system includes a data exchange engine and a number of adapters associated with a corresponding number of applications. Each of the adapters is customized to interface with a corresponding application and transforms the data being transferred between the application and the data exchange engine. Data produced by a particular application is converted from a technology dependent form to a technology independent form by the corresponding adapter.
In one embodiment, the format associated with a data stream is disassociated from the informational content of the data stream by the adapter. The informational content of the data stream is then transformed by the adapter into a common or generic format. The data exchange engine receives data in a technology independent form from each of its associated adapters and coordinates the routing of informational content to particular adapters associated with applications that have requested specific informational content. The adapters receiving the informational content from the data exchange engine transform the informational content having the common format into a data format compatible with, or specific to, their associated applications. In one embodiment, a queuing mechanism is employed to construct a reliable asynchronous or pseudo-synchronous interface between disparate applications and systems.
The data exchange engine may apply business rules or logic when processing a request for particular informational content. An application, for example, may require informational content produced by a number of different applications. The data exchange engine obtains, organizes, and processes the multiple source informational content as dictated by user-specific business logic. Changes to processing and organizational requirements for a particular user or application are effected simply by modifying the user-specific business logic, rather than data exchange engine code.
User-specified routing logic may be applied by the data exchange engine to dispatch selected informational content to one or more destination applications. As with the business logic, changes in routing requirements are effected simply by modifying the routing logic, rather than data exchange engine code.
Process monitoring, tracing, and logging are provided to track the progress of data passing through the data exchange engine and to detect and correct processing errors. In the case of a processing anomaly, the data exchange engine effects a rollback of failed transactions to preclude the loss of data. Performance statistics may also be provided.
A wide variety of interfaces may be developed by appropriate deployment of adapters and one or more data exchange engines. Proprietary back-end systems having only a single user-interface, for example, may be logically transformed into an open system having multi-user Web intefaces. Unreliable applications may be stabilized by employment of the data exchange infrastructure. Disparate
Fischer Larry J.
Himabindu Gurla
Hu Qilin
Matthews Richard W.
Mow Boyle Y.
ADC Telecommunications Inc.
Courtenay III St. John
Nguyen Van H.
Schwegman Lundberg Woessner & Kluth P.A.
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