Abstract: A computer implemented method for replacing components of a data processing system, comprising in response to a detection of a newly added component at a specific location; reading its customization data from a data storage and querying a persistent database to determine if functional capabilities according to customization data are specified for this specific location; depending on a result of determining the functional capabilities and of querying the database if it contains customization data either: disabling the component; or enabling the component and storing in the database the customization data; or enabling the component and replacing the customization data in the database; or storing the customization data in the data storage of the component and enabling the component.

Abstract: An adjustable attenuation wrap plug for insertion into a signal port at an end product includes a housing with a protruding input prong and output prong, wherein a signal cable is coupled to the input prong and the output prong. The adjustable attenuation wrap plug further includes a ratchet mechanism at least partially disposed in the housing, wherein the ratchet mechanism is configurable to alter a shape of the signal cable.

Abstract: An apparatus for an attenuation adjustment tool, the attenuation adjustment tool includes a body with an adjustment arm positioned at a first side of the body, where an actuator is configured to extend and retract the adjustment arm. The attenuation adjustment tool further includes an input port and an output port positioned at the first side of the body, wherein an input prong and an output prong of a wrap plug are each respectively insertable into the input port and the output port. The attenuation adjustment tool further includes the adjustment arm configurable to engage with a mechanism on the wrap plug, wherein the mechanism is configurable to alter a shape of a signal cable in the wrap plug.

Abstract: An apparatus for an attenuation adjustment tool, the attenuation adjustment tool includes a body with an adjustment arm positioned at a first side of the body, where an actuator is configured to extend and retract the adjustment arm. The attenuation adjustment tool further includes an input port and an output port positioned at the first side of the body, wherein an input prong and an output prong of a wrap plug are each respectively insertable into the input port and the output port. The attenuation adjustment tool further includes the adjustment arm configurable to engage with a mechanism on the wrap plug, wherein the mechanism is configurable to alter a shape of a signal cable in the wrap plug.

Abstract: An adjustable attenuation wrap plug for insertion into a signal port at an end product includes a housing with a protruding input prong and output prong, wherein a signal cable is coupled to the input prong and the output prong. The adjustable attenuation wrap plug further includes a ratchet mechanism at least partially disposed in the housing, wherein the ratchet mechanism is configurable to alter a shape of the signal cable.

Abstract: A method of using an adjustable attenuation fiber optic wrap plug (“AAFOWP”) includes receiving initial data into a wireless module of the AAFOWP, wherein the initial data corresponds to an initial desired attenuation level that the first AAFOWP is to achieve. The method also includes moving, in response to receiving the initial data, an arm by an actuator to change a bend radius of an optical fiber wrap in the AAFOWP, thus adjusting an attenuation through the AAFOWP to the initial desired attenuation level.

Abstract: A computer implemented method for replacing components of a data processing system, comprising in response to a detection of a newly added component at a specific location; reading its customization data from a data storage and querying a persistent database to determine if functional capabilities according to customization data are specified for this specific location; depending on a result of determining the functional capabilities and of querying the database if it contains customization data either: disabling the component; or enabling the component and storing in the database the customization data; or enabling the component and replacing the customization data in the database; or storing the customization data in the data storage of the component and enabling the component.

Abstract: Embodiments include techniques for device analysis and failure prediction, the techniques include measuring or collecting parametric data of the device at a configurable interval, wherein the parametric data includes one or more parameters, and receiving operating limits for the parametric data based on specifications or characteristics for the device. The techniques also include determining a trend of the measured or collected parametric data of the device, and filtering noise from the trend based at least in part on at least one of other devices exhibiting a deviation exhibited by the device or system state changes associated with system log files. The techniques include identifying a failure stage of the device based on at least one of the trend or the received operating limits, and transmitting a notification of a predicted failure based at least in part on the identification.

Abstract: Embodiments include techniques for device analysis and failure prediction, the techniques include measuring or collecting parametric data of the device at a configurable interval, wherein the parametric data includes one or more parameters, and receiving operating limits for the parametric data based on specifications or characteristics for the device. The techniques also include determining a trend of the measured or collected parametric data of the device, and filtering noise from the trend based at least in part on at least one of other devices exhibiting a deviation exhibited by the device or system state changes associated with system log files. The techniques include identifying a failure stage of the device based on at least one of the trend or the received operating limits, and transmitting a notification of a predicted failure based at least in part on the identification.

Abstract: Processing, such as debug and/or recovery processing, within a communications environment is facilitated. Responsive to detecting an event, a stop signal is propagated through a communications network of the communications environment, and each network element that receives the stop signal, transmits the signal to its neighbors (if any), and then performs an action depending on its specific programming. The action can be to take no action, perform a debugging action or perform a recovery action. The elements that receive the signal and perform the same action as other elements form a coordinated network providing a coordinated result.

Abstract: Processing, such as debug and/or recovery processing, within a communications environment is facilitated. Responsive to detecting an event, a stop signal is propagated through a communications network of the communications environment, and each network element that receives the stop signal, transmits the signal to its neighbors (if any), and then performs an action depending on its specific programming. The action can be to take no action, perform a debugging action or perform a recovery action. The elements that receive the signal and perform the same action as other elements form a coordinated network providing a coordinated result.

Abstract: Fast error reporting is provided in networks that have an architected delayed error reporting capability. Errors are detected and reported without having to wait for a timeout period to expire. Further, failures of other components caused by the delay are avoided, since the delay is bypassed.

Abstract: Fast error reporting is provided in networks that have an architected delayed error reporting capability. Errors are detected and reported without having to wait for a timeout period to expire. Further, failures of other components caused by the delay are avoided, since the delay is bypassed.

Abstract: Processing, such as debug and/or recovery processing, within a communications environment is facilitated. Responsive to detecting an event, a stop signal is propagated through a communications network of the communications environment, and each network element that receives the stop signal, transmits the signal to its neighbors (if any), and then performs an action depending on its specific programming. The action can be to take no action, perform a debugging action or perform a recovery action. The elements that receive the signal and perform the same action as other elements form a coordinated network providing a coordinated result.

Abstract: Fast error reporting is provided in networks that have an architected delayed error reporting capability. Errors are detected and reported without having to wait for a timeout period to expire. Further, failures of other components caused by the delay are avoided, since the delay is bypassed.

Abstract: Processing, such as debug and/or recovery processing, within a communications environment is facilitated. Responsive to detecting an event, a stop signal is propagated through a communications network of the communications environment, and each network element that receives the stop signal, transmits the signal to its neighbors (if any), and then performs an action depending on its specific programming. The action can be to take no action, perform a debugging action or perform a recovery action. The elements that receive the signal and perform the same action as other elements form a coordinated network providing a coordinated result.

Abstract: A server Input/Output (I/O) drawer for holding one or more communication cards and one or more I/O cards includes an outer housing, a back plane within the outer housing that divides the drawer into a front portion and back portion, the back plane including a front side and a backside and configured to receive the one or more I/O cards and the one or more communications cards, and an air movement device (AMD) disposed within the front portion, a distribute current assembly (DCA) that receives a voltage from an external source and supplies power, through the backplane, to the AMD.