A self-adaptive field device is disclosed having a repository, an identity register and a firmware framework having static firmware modules. Further disclosed is an industrial automation system of self-adaptive field devices, and a method for configuring such a system. The method includes booting each field device, evaluating each field device, and initialising each field device. The method may further include resource load balancing.

A machine automation system for controlling and operating an automated machine. The system includes a controller and sensor bus including a central processing core and a multi-medium transmission intranet for implementing a dynamic burst to broadcast transmission scheme where messages are burst from nodes to the central processing core and broadcast from the central processing core to all of the nodes.

The present disclosure relates to a method for parameterizing an automation field device which is communicatively connected to a server, having the following steps: initiating the method by transmitting a command to parameterize the field device on the server; transmitting identification information of the field device to the server; ascertaining a digital image of the field device stored on the server using the transmitted identification information, said digital image containing configuration settings of the field device and measurement location-relevant information and being designed to reproduce the behavior of the field device in a simulated or emulated manner; generating and proposing a parameter set for the field device using the field device information; selecting and confirming the proposed parameter set by a user; and transmitting the confirmed parameter set to the field device and parameterizing the field device using the transmitted parameter set.

A self-adaptive field device is disclosed having a repository, an identity register and a firmware framework having static firmware modules. Further disclosed is an industrial automation system of self-adaptive field devices, and a method for configuring such a system. The method includes booting each field device, evaluating each field device, and initialising each field device. The method may further include resource load balancing.

An HVAC controller may be configured to control any of a variety of different types of HVAC systems that may include any of a variety of different HVAC components. The HVAC controller may be configured to solicit inputs from an installer or other user that enables the HVAC controller to help prioritize installer setup parameter settings for the HVAC controller to properly control the particular HVAC equipment that is present at the installation.

A system is disclosed for configuring a motor controller using a one-click configuration scheme, simplifying the process of motor configuration in drives and similar devices. The system includes a specify component, a display component, and a single-action identification and configuration component. The specify component specifies a motor in communication with the motor controller. The display component displays information on the status of the motor controller. The single-action identification and configuration component, in response to performance of only a single action (i.e., a single-click or equivalent starting signal), performs an identification and configuration sequence for the motor comprising at least three identification steps to establish a single parameter for driving the motor. The at least three identification steps can include measurements of system parameters, noise, and resonance. The recommend bandwidth for motor operation can be selected from within a range of permissible bandwidths.

An embedded system has a data processing apparatus that executes program code and a sequencing controller for switching components of the embedded system on and off, the data processing apparatus and the sequencing controller connected to one another via an individual control signal line, and the sequencing controller arranged to either switch off or restart the embedded system on the basis of a temporal profile of a control signal received via the control signal line.

A system is disclosed for configuring a motor controller using a one-click configuration scheme, simplifying the process of motor configuration in drives and similar devices. The system includes a specify component, a display component, and a single-action identification and configuration component. The specify component specifies a motor in communication with the motor controller. The display component displays information on the status of the motor controller. The single-action identification and configuration component, in response to performance of only a single action (i.e., a single-click or equivalent starting signal), performs an identification and configuration sequence for the motor comprising at least three identification steps to establish a single parameter for driving the motor. The at least three identification steps can include measurements of system parameters, noise, and resonance. The recommend bandwidth for motor operation can be selected from within a range of permissible bandwidths.

The disclosure extends to methods, systems, and computer program products for generating and optimizing irrigation protocols. The disclosure extends to methods, systems, and computer program products for optimizing water usage in growing plants for yard and crops. The disclosure also extends to methods, systems and computer program products for providing automated irrigation.

The disclosure extends to methods, systems, and computer program products for generating and optimizing irrigation protocols. The disclosure extends to methods, systems, and computer program products for optimizing water usage in growing plants for yard and crops. The disclosure also extends to methods, systems and computer program products for providing automated irrigation.