The present invention discloses a diode array-based digitized miniature ultra-low-power-consumption impact monitoring system, which belongs to the technical field of aircraft structural health monitoring. The impact monitoring system consists of a miniature sensor array interface, a passive band-pass filter array, a diode array, a digital conversion and management module, an on-board bus communication module, a monitoring data storage module, a self-powering module, and a miniature communication and power supply interface. According to the impact monitoring system, the amplitudes of impact response signals are controlled within a clamp voltage range of diodes by using the diode array, thereby realizing the first-stage digitization; and the second-stage digitization of the impact response signals is realized by using the digital conversion and management module consisting of a miniature field programmable gate array of ultra-low-power-consumption. The impact monitoring system can realize on-line, real-time and uninterrupted impact monitoring on large-scale aircraft structures, thereby improving the safety and maintenance efficiency of the aircraft structures.

A procedure for changing, in particular for updating a control program of an input/output module (I/O module), wherein the I/O module is attached side-by-side to a head station of a modular fieldbus node, said procedure comprising transferring data describing the change from the head station via a local bus to the I/O module, wherein the local bus connects the head station to the I/O module, checking the compatibility of the I/O module with the change by the I/O module, and transferring feedback, based on the checked compatibility of the I/O module, from the I/O module via the local bus to the head station; a correspondingly configured I/O module is also presented.

A procedure for changing, in particular for updating a control program of an input/output module (I/O module), wherein the I/O module is attached side-by-side to a head station of a modular fieldbus node, said procedure comprising transferring data describing the change from the head station via a local bus to the I/O module, wherein the local bus connects the head station to the I/O module, checking the compatibility of the I/O module with the change by the I/O module, and transferring feedback, based on the checked compatibility of the I/O module, from the I/O module via the local bus to the head station; a correspondingly configured I/O module is also presented.

An Internet Protocol (IP)-enabled smart transducer includes a sensor for generating field data regarding a physical quantity associated with processing equipment or a device in an industrial processing facility, and a signal conditioning circuit for at least one of amplifying and filtering the field data to provide conditioned field data. A communications interface is coupled to the signal conditioning circuit including a processor having an associated memory and a field data to IP data conversion algorithm for generating the IP data from the conditioned field data, and a transmitter is for transmitting the IP data across an IP bus to at least one application connected to the IP bus.

A system includes a high speed bus and a plurality of multi-function modules coupled to the high speed bus. The plurality of multi-function modules includes at least one controller configured to execute control logic for the system. The plurality of multi-function modules also includes at least one arbitrator configured to manage the at least one controller. The plurality of multi-function modules further includes at least one input/output (IO) manager configured to interface between the at least one controller and at least one field device.

Systems and methods of the subject invention provide for the communication with field devices in a first fieldbus system working in accordance with a first standard, and in a second fieldbus system working in accordance with a second standard. First and second field devices are arranged in the first fieldbus system and are coupled via a first fieldbus in accordance with the first standard. The first field device is also coupled to the second fieldbus system working in accordance with a second standard. A standardized object in accordance with the first standard is loaded on the first field device. A description of the standardized object is provided in the second fieldbus system. The standardized object is used from the second fieldbus system, the standardized object having no definition of a data type.

The present invention discloses a diode array-based digitized miniature ultra-low-power-consumption impact monitoring system, which belongs to the technical field of aircraft structural health monitoring. The impact monitoring system consists of a miniature sensor array interface, a passive band-pass filter array, a diode array, a digital conversion and management module, an on-board bus communication module, a monitoring data storage module, a self-powering module, and a miniature communication and power supply interface. According to the impact monitoring system, the amplitudes of impact response signals are controlled within a clamp voltage range of diodes by using the diode array, thereby realizing the first-stage digitization; and the second-stage digitization of the impact response signals is realized by using the digital conversion and management module consisting of a miniature field programmable gate array of ultra-low-power-consumption. The impact monitoring system can realize on-line, real-time and uninterrupted impact monitoring on large-scale aircraft structures, thereby improving the safety and maintenance efficiency of the aircraft structures.

An Internet Protocol (IP)-enabled smart transducer includes a sensor for generating field data regarding a physical quantity associated with processing equipment or a device in an industrial processing facility, and a signal conditioning circuit for at least one of amplifying and filtering the field data to provide conditioned field data. A communications interface is coupled to the signal conditioning circuit including a processor having an associated memory and a field data to IP data conversion algorithm for generating the IP data from the conditioned field data, and a transmitter is for transmitting the IP data across an IP bus to at least one application connected to the IP bus.

A system includes a high speed bus and a plurality of multi-function modules coupled to the high speed bus. The plurality of multi-function modules includes at least one controller configured to execute control logic for the system. The plurality of multi-function modules also includes at least one arbitrator configured to manage the at least one controller. The plurality of multi-function modules further includes at least one input/output (IO) manager configured to interface between the at least one controller and at least one field device.

Systems and methods of the subject invention provide for the communication with field devices in a first fieldbus system working in accordance with a first standard, and in a second fieldbus system working in accordance with a second standard. First and second field devices are arranged in the first fieldbus system and are coupled via a first fieldbus in accordance with the first standard. The first field device is also coupled to the second fieldbus system working in accordance with a second standard. A standardized object in accordance with the first standard is loaded on the first field device. A description of the standardized object is provided in the second fieldbus system. The standardized object is used from the second fieldbus system, the standardized object having no definition of a data type.