Abstract: The architecture design and functional operation of an enterprise data processing system with distributed intelligence capable of monitoring sensor networked systems and processing large sets of data as required by the application is disclosed in this invention. The system is based on smart sensor/actuator nodes, local processing units, a server, and clients. Smart nodes interface with transducers for conducting data acquisition or control and consist of a small processor, a communications module, and transducer interfacing circuitry. The processor includes instructions to execute commands and may contain small-form factor processing algorithms. Sensor and processed data is then transmitted to the local processing units which perform higher level processing and contain functions for managing the nodes. The local processing units have small databases that are updated with the status of the monitored system. These devices then communicate with a server based on commands and automated event messages.

Abstract: A Coremicro Reconfigurable Embedded Smart Sensor Node has the capability of hosting intelligent algorithms to support health monitoring applications and has optional standardized software communications stack. The purpose of this present invention is to provide a flexible low power distributed computational platform to deploy intelligent software elements (based on Artificial Intelligence techniques) among the system architecture to result in a reconfigurable scheme for distributed intelligence granularity. This invention is able to be applied to a wide variety of monitoring applications either as a Standalone Smart Sensor (SSS, i.e. single Smart Sensor Node) or as a modular and scalable Smart Sensor Network configuration. Therefore, the CRE-SSN is ultra-low in power consumption, has optional pattern recognition through Artificial Neural Network, physical communication layer reconfigurable capability, has scalable communications capability, and low in weight, and optimized in size.

Abstract: A miniature in-vivo robotic module to be used for conducting dexterous manipulations on organs and other target entities in a patient's abdominal or peritoneal cavity as part of Natural Orifice Transluminal Endoscopic Surgery (NOTES) is disclosed in this invention. The robotic module is a serial manipulator consisting of seven cylindrical links and six actively controllable rotational degrees of freedom, thereby enabling an end effector equipped with a laparoscopic type instrument to assume a commanded position and orientation within the robot's workspace. After overtube navigation starting from a natural orifice or preexisting wound, the module must be anchored and guided to a designated location along the inner abdominal cavity wall. This is accomplished via magnetic coupling forces between internal embedded magnets and magnets fixed to the end of a different robotic manipulator located external to the patient.

Abstract: A miniature in-vivo robotic module to be used for conducting dexterous manipulations on organs and other target entities in a patient's abdominal or peritoneal cavity as part of Natural Orifice Transluminal Endoscopic Surgery (NOTES) is disclosed in this invention. The robotic module is a serial manipulator consisting of seven cylindrical links and six actively controllable rotational degrees of freedom, thereby enabling an end effector equipped with a laparoscopic type instrument to assume a commanded position and orientation within the robot's workspace. After overtube navigation starting from a natural orifice or preexisting wound, the module must be anchored and guided to a designated location along the inner abdominal cavity wall. This is accomplished via magnetic coupling forces between internal embedded magnets and magnets fixed to the end of a different robotic manipulator located external to the patient.