Abstract: Examples are disclosed that relate to computing systems having a common conductive pathway. One example provides a computing system comprising a power supply configured to output electrical power for delivery to one or more power nodes, and one or more power monitors configured to identify a power overload condition based on the power output by the power supply. The computing system further comprises a parent controller configured to, based at least on receiving an indication of the power overload condition, transmit an instruction to one or more child controllers that causes each child controller to effect a change in an operational state of a corresponding power node. The computing system also comprises a conductive pathway along which electrical power output from the power supply is transmitted for delivery to the one or more power nodes, and along which the instruction is transmitted to the one or more child controllers.

Abstract: Examples are disclosed that relate to computing systems having a common conductive pathway. One example provides a computing system comprising a power supply configured to output electrical power for delivery to one or more power nodes, and one or more power monitors configured to identify a power overload condition based on the power output by the power supply. The computing system further comprises a parent controller configured to, based at least on receiving an indication of the power overload condition, transmit an instruction to one or more child controllers that causes each child controller to effect a change in an operational state of a corresponding power node. The computing system also comprises a conductive pathway along which electrical power output from the power supply is transmitted for delivery to the one or more power nodes, and along which the instruction is transmitted to the one or more child controllers.

Abstract: A facility control service and programmable logic controller (PLC) interfaces enable coordination and optimization of control of various PLCs that use various PLC specific protocols. The facility control service sends control commands formatted in accordance with a secure protocol and respective PLC interfaces convert the control commands into respective PLC specific protocols. In some embodiments, a facility control service employs machine learning techniques to optimize control of PLCs at a facility. Also, in some embodiments, a facility control service coordinates deployment of PLC software to various PLCs in one or more facilities that use various PLC specific protocols.

Abstract: Air quality inside a computing device is monitored utilizing an air quality monitor that can be sized to simulate a server computing device and can have multiple sensing equipment mounted inside, including equipment to detect corrosive aspects in the air and condensation sensing equipment to detect instances in which condensation can form on computing device hardware. Corrosion sensing can include metallic members that can be electrically coupled to voltage that can induce a current within the metallic members, thereby more accurately simulating the corrosion of operating PCBs. Condensation sensing can include condensation hosting members that can have a thermal mass that is approximately equal to the thermal mass of PCBs and can include heating elements by which the condensation hosting members can more accurately simulate the thermal effects and aspects of operating PCBs, and also moisture detectors, including electrical and optical moisture detectors. Additionally, an off-gassing chamber can be included.

Abstract: Techniques are described herein that are capable of performing RFID-based navigation of an autonomous guided vehicle (AGV). An intended location of the AGV is determined based at least in part on a previously determined location of the AGV and further based at least in part on a calculated motion of the AGV from the previously determined location. The AGV includes an RFID device that is paired with RFID devices in an environment of the AGV. The RFID device of the AGV and one or more of the RFID devices in the environment may communicate in accordance with an RFID technique to enable the AGV to determine an actual location of the AGV. A reference location of the AGV on which navigation of the AGV is based is set to be the actual location rather than the intended location.

Abstract: Air quality inside a computing device is monitored utilizing an air quality monitor that can be sized to simulate a server computing device and can have multiple sensing equipment mounted inside, including equipment to detect corrosive aspects in the air and condensation sensing equipment to detect instances in which condensation can form on computing device hardware. Corrosion sensing can include metallic members that can be electrically coupled to voltage that can induce a current within the metallic members, thereby more accurately simulating the corrosion of operating PCBs. Condensation sensing can include condensation hosting members that can have a thermal mass that is approximately equal to the thermal mass of PCBs and can include heating elements by which the condensation hosting members can more accurately simulate the thermal effects and aspects of operating PCBs, and also moisture detectors, including electrical and optical moisture detectors. Additionally, an off-gassing chamber can be included.

Abstract: A monitoring system may receive data indicating work performed by a set of computing devices during a given period of time and may receive data indicating an amount of power consumed by the set of computing devices and support systems that support the set of computing devices during the given period of time. The monitoring system may normalize the amounts of work performed by different types of computing devices in the set and determine an aggregate amount of work performed by the set. The monitoring system may also determine an aggregate amount of electrical power consumed by the set of computing devices and support system that support the set of computing devices during the given period of time. A monitoring system may use the aggregate amount of work performed and aggregate amount of power consumed during the given period of time to determine a performance index efficiency for the set.

Abstract: A virtual temperature monitoring system in a data center communicates with servers mounted in racks to receive internal temperature data generated by internal temperature sensors of the servers. The system derives a virtual sensor measurement of external temperatures external to the server, including a portion of a cold aisle that extends proximate to a rack in which the server is mounted, based upon a relationship between the received internal temperature sensors and the external environment. Sensor data from other sensors can be received via a building management system, and building management signals to the building management system can be generated based at least partially on the virtual sensor data. The virtual sensor data can be used to generate a graphical representation of the servers that highlights relative thermal characteristics of the servers based on the virtual external sensor measurements, including heat indices, excursions beyond thresholds, historical excursion histories, etc.

Abstract: A computer room includes rack mounted computing devices and multiple air handling systems for cooling the computer room. A model based cooling control system is implemented on resources of a provider network that includes the rack mounted computing devices. The model based cooling control system uses a model of the computer room to iteratively perform calculations to determine a set of control parameters for cooling the computer room. The set of control parameters are selected to reduce or optimize an amount of energy and/or water used to cool the computer room while satisfying one or more conditions for cooling the computer room such as a maximum allowable temperature of the room and/or a maximum allowable temperature of the rack mounted computing devices in the computer room.

Abstract: A virtual temperature monitoring system in a data center communicates with servers mounted in racks to receive internal temperature data generated by internal temperature sensors of the servers. The system derives a virtual sensor measurement of external temperatures external to the server, including a portion of a cold aisle that extends proximate to a rack in which the server is mounted, based upon a relationship between the received internal temperature sensors and the external environment. Sensor data from other sensors can be received via a building management system, and building management signals to the building management system can be generated based at least partially on the virtual sensor data. The virtual sensor data can be used to generate a graphical representation of the servers that highlights relative thermal characteristics of the servers based on the virtual external sensor measurements, including heat indices, excursions beyond thresholds, historical excursion histories, etc.

Abstract: A virtual temperature monitoring system in a data center communicates with servers mounted in racks to receive internal temperature data generated by internal temperature sensors of the servers. The system derives a virtual sensor measurement of external temperatures external to the server, including a portion of a cold aisle that extends proximate to a rack in which the server is mounted, based upon a relationship between the received internal temperature sensors and the external environment. Sensor data from other sensors can be received via a building management system, and building management signals to the building management system can be generated based at least partially on the virtual sensor data. The virtual sensor data can be used to generate a graphical representation of the servers that highlights relative thermal characteristics of the servers based on the virtual external sensor measurements, including heat indices, excursions beyond thresholds, historical excursion histories, etc.

Abstract: A virtual temperature monitoring system in a data center communicates with servers mounted in racks to receive internal temperature data generated by internal temperature sensors of the servers. The system derives a virtual sensor measurement of external temperatures external to the server, including a portion of a cold aisle that extends proximate to a rack in which the server is mounted, based upon a relationship between the received internal temperature sensors and the external environment. Sensor data from other sensors can be received via a building management system, and building management signals to the building management system can be generated based at least partially on the virtual sensor data. The virtual sensor data can be used to generate a graphical representation of the servers that highlights relative thermal characteristics of the servers based on the virtual external sensor measurements, including heat indices, excursions beyond thresholds, historical excursion histories, etc.