There is provided a drive control apparatus that can maintain a drive control system to be in a safe state even in a case where operational abnormality of avoiding a normal reset of a control processor or operational abnormality of avoiding solution even after resetting the control processor occurs in the control processor. The control processor includes an actuator control processing unit configured to generate a control signal for a drive circuit being a control target apparatus and an actuator, and a diagnosis processing unit configure to diagnosing the actuator control processing unit. The diagnosis processing unit cyclically outputs a reset signal to WDT in a case where the operation of the control processor is normal. The WDT continuously outputs a cutoff signal for cutting off a supply of the control signal from the control processor to the control target apparatus when the cyclic reset signal stops.

A method, system and computer program product are provided for implementing anomaly detection and notification through profiled context. Anomalies are detected by effectively using multiple devices and using predefined profiles to generate a contextual comparison for subtle differences detected. When predefined subtle anomalies are detected using at least one of the predefined profiles, a selected notification is provided.

A method of operating a sapling hydrating system for a planting apparatus. The method comprising determining a release pressure of hydrating fluid for a release valve to hydrate a sapling based on a target distribution rate of the hydrating fluid, wherein the target distribution rate is received via an input signal. The method further comprising controlling a supply pressure of the hydrating fluid from a pump to be greater than or equal to the release pressure, and controlling an unloading valve fluidly disposed between the pump and a hydrating fluid storage tank. The unloading valve regulating a maximum supply pressure. The method further includes controlling the release valve to provide a first portion of the hydraulic fluid to the release valve at an unloading pressure greater than or equal to the release pressure, and directing the remainder of the hydrating fluid back to the storage tank.

In order to easily identify a specimen to be extracted because, for example, an item remains uninspected, from a rack 31 collected in a storage part 13 or the rack 31 taken out from the storage part, a camera of a smart device takes an image of the rack; and a calculation unit included in the smart device provides a mark, by AR technology, at the position of a specimen to be extracted. For example, the item that remains uninspected is identified on the basis of information about a combination of a rack ID and an identifier and information, which is received from an operation unit about specimens at respective positions. Thus, irrespective of a place or whether the specimen to be extracted is inside or outside of the device, the specimen to be extracted can be reliably specified from a plurality of specimen containers provided on a holder.

A method, system and computer program product are provided for implementing anomaly detection and notification through profiled context. Anomalies are detected by effectively using multiple devices and using predefined profiles to generate a contextual comparison for subtle differences detected. When predefined subtle anomalies are detected using at least one of the predefined profiles, a selected notification is provided.

1. Room control system for a room-in-room (6), comprising at least one input unit (1), at least one display unit (2) and a data processing system (3) interacting with the input unit (1) and the display unit (2), where with the data processing system (3) at least one technical device (4) can be selected and at least one service function can be realised with the technical device (4).

The present invention provides an improved system, device and method for reliably commissioning application devices within an application control network that scales well even with large installations of the respective application control systems. Instead of relying on a direct physical identification of the application devices installed at a specific position, e.g. in a building, the commissioning is based on feedback on trigger events and relative positions of the application devices. In a system comprising a commissioning device and a commissioning base station having access to an application plan the commissioning device is communicatively connected with the commissioning base station and is adapted to determine a relative position of a first application device that is communicatively coupled with an application control network. The commissioning device is further adapted to interact with the commissioning base station to trigger a reaction of the first application device and to verify that the reaction occurred. The system is adapted to create a corresponding application plan entry for the first application devices upon verification of the reaction.

In order to easily identify a specimen to be extracted because, for example, an item remains uninspected, from a rack 31 collected in a storage part 13 or the rack 31 taken out from the storage part, a camera of a smart device takes an image of the rack; and a calculation unit included in the smart device provides a mark, by AR technology, at the position of a specimen to be extracted. For example, the item that remains uninspected is identified on the basis of information about a combination of a rack ID and an identifier and information, which is received from an operation unit about specimens at respective positions. Thus, irrespective of a place or whether the specimen to be extracted is inside or outside of the device, the specimen to be extracted can be reliably specified from a plurality of specimen containers provided on a holder.

There is provided a drive control apparatus that can maintain a drive control system to be in a safe state even in a case where operational abnormality of avoiding a normal reset of a control processor or operational abnormality of avoiding solution even after resetting the control processor occurs in the control processor. The control processor includes an actuator control processing unit configured to generate a control signal for a drive circuit being a control target apparatus and an actuator, and a diagnosis processing unit configure to diagnosing the actuator control processing unit. The diagnosis processing unit cyclically outputs a reset signal to WDT in a case where the operation of the control processor is normal. The WDT continuously outputs a cutoff signal for cutting off a supply of the control signal from the control processor to the control target apparatus when the cyclic reset signal stops.

A system for monitoring and managing environmental condition(s) in a data center is disclosed. The system includes a monitoring entity 20 which gets activated when worn by a first user. The system also includes a controller unit 30 which includes a processing subsystem including a tracking module 50 which records attendance for the first user. The processing subsystem also includes a monitoring module 60 which receives parameter(s) corresponding to the environmental condition(s), when the first user initiates a routine-monitoring walk. The processing subsystem also includes a zoning module 90 which performs zoning of the data center-associated sensor(s). The processing subsystem also includes a zone identification module 100 which identifies issue-related zone(s) based on a comparison of the parameter(s) with corresponding threshold parameter(s). The processing subsystem also includes an issue addressing module 110 which generates an issue-related alert and prioritizes at least one of the issue-related zone(s), thereby monitoring and managing the environmental condition(s) in the data center.