Methods and apparatus to design collaborative automation systems based on data distribution service middleware

The invention claimed is: 1. A clustered automation platform, comprising: one or more control servers at a non-field location connected to a local area control network; a plurality of self-contained process interface systems at respective field locations remote from the non-field location configured to receive electrical signals from respective one or more field instruments via hardwiring and forward resulting data via an uplink to a local area input/output network; one or more input/output processing and inferential modeling servers at the non-field location connected to the local area input/output network and configured to process input/output signals of the plurality of self-contained process interface systems; and real-time data distribution service (DDS) control middleware configured to interconnect one or more process control applications, the one or more input/output processing and inferential modeling servers, the one or more control servers, the plurality of self-contained process interface systems, and one or more human machine interfaces (HMIs), wherein each of the plurality of self-contained process interface systems is a standalone input/output system, decoupled from the one or more control servers such that a dynamic soft association is provided between the plurality of self-contained process interface systems and the one or more control servers, rather than a static and physical association, enabled by the real-time DDS control middleware, and each of the plurality of self-contained process interface systems has associated hardware for connection to the one or more field instruments and configured according to a compact physical configuration, a fixed physical configuration, or a mixed physical configuration, and wherein each said input/output processing and inferential modeling server is assigned to a respective self-contained process interface system and configured to process the resulting data of the respective self-contained process interface system, and infer unmeasured process properties from the processed resulting data of the respective self-contained process interface system for the one or more process control applications. 2. The clustered automation platform of claim 1 , wherein the clustered automation platform comprises commercial off-the-shelf (COTS) components. 3. The clustered automation platform of claim 1 , wherein each of the plurality of self-contained process interface systems comprises a junction box. 4. The clustered automation platform of claim 1 , wherein one of the plurality of self-contained process interface systems comprises a master self-contained process interface system. 5. The clustered automation platform of claim 1 , wherein each of the one or more control servers is configured to host a single control application running continuously on a real-time operating system. 6. The clustered automation platform of claim 1 , wherein the real-time data distribution service control middleware is configured to provide publish and subscribe communication between the process control applications and the local area control network. 7. The clustered automation platform of claim 1 , wherein the clustered automation platform is configured for use within processing facilities in oil and gas, petrochemical, pharmaceutical, water/wastewater treatment, manufacturing, aerospace, travel, food, textile, film, hospital, leisure, foundry, agriculture, plastic, or printing industries. 8. The clustered automation platform of claim 1 , wherein the one or more control servers comprise one or more of a sequential and regulatory controller, an advanced regulatory controller, a multivariable controller, a unit-based process controller, or a plant-wide advanced process controller. 9. The clustered automation platform of claim 1 , wherein one of the self-contained process interface systems comprises an Ethernet switch uplink connected to the local area input/output network, the local area input/output network including a fault-tolerant high-performance Ethernet network. 10. The clustered automation platform of claim 1 , wherein each of the plurality of self-contained process interface systems are configured to operate autonomously. 11. The clustered automation platform of claim 1 , wherein each said input/output processing and inferential modeling server is further configured to generate applicable alarms corresponding to the processed resulting data of the respective self-contained process interface system and the unmeasured process properties from the processed resulting data of the respective self-contained process interface system for the one or more process control applications. 12. A method of providing real-time communication, the method comprising: receiving, via an autonomous process interface system at a field location, electrical signals of status updates from one or more field instruments; converting, via the autonomous process interface system, the electrical signals to digital data; assigning, via a master autonomous process interface system at a non-field location remote from the field location, an input/output processing and inferential modeling server to process the digital data; transmitting, via the master autonomous process interface system, the digital data to the input/output processing and inferential modeling server; inferring, via the input/output processing and inferential modeling server, unmeasured process properties from the transmitted digital data; and publishing changed values within the transmitted digital data and the unmeasured process properties from the transmitted digital data from the input/output processing and inferential modeling server to one or more subscribers, wherein the transmitting and the publishing are executed via real-time data distribution service (DDS) control middleware, and wherein the autonomous process interface system is a standalone input/output system, decoupled from the master autonomous process interface system such that a dynamic soft association is provided between the autonomous process interface system and the master autonomous process system, rather than a static and physical association, and enabled by the real-time DDS control middleware and the autonomous process interface system has associated hardware for connection to the one or more field instruments. 13. The method of claim 12 , further comprising: recording a sequence of events from the transmitted digital data. 14. The method of claim 12 , wherein the transmitting occurs via an Ethernet switch uplink connected from the autonomous process interface system to the input/output processing and inferential modeling server. 15. The method of claim 12 , further comprising: generating applicable alarms corresponding to the changed values of the received converted field instrument data and the unmeasured process properties from the converted field instrument data for the process control applications. 16. A collaborative automation system, comprising: a master autonomous process interface input/output system at a non-field location connected to a plurality of autonomous process interface input/output subsystems at respective field locations remote from the non-field location, wherein each of the plurality of autonomous process interface input/output subsystems is connected to one or more field instruments; an input/output processing and inferential modeling server assigned to a respective autonomous process interface input/output subsystem and configured to receive converted field instrument data from the master autonomous process interface input/output