Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node. The commissioning system then transmits the set of parameters, including one or more group addresses, to the applicable mesh node, for each affected mesh node in the network.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A consumable-goods reordering system in which a system controller has access to the signals transmitted by each smart appliance relevant to the environment being monitored, such as a home. Each appliance monitors a particular physical condition that is related to the appliance's usage of a consumable good, senses changes in the condition being monitored, and reports states of the condition. Meanwhile, the system controller memorizes and maintains the states of various processing events, such as when an appliance reported a particular state of the monitored condition. By considering the information reported by the multiple smart appliances, as well as by accounting for the states corresponding to the various events, the system controller is able to continually update a representation of the state of the monitored environment. Having such context awareness enables the system controller to generate intelligently various reorder messages for transmission to the various suppliers of the consumables.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A motorized system that allows for calibration by a user, and that features circuit protection and detection of motor stoppage. A motorized window-blind system is an example of such a system and is disclosed herein. In particular, a circuit is featured that comprises a TRIAC, or “triode for alternating current,” and TVS diodes, or “transient-voltage-suppression diodes,” providing voltage protection to various types of motor-related electronic components. A controller is disclosed that features measurement of voltage that is induced on a secondary winding of a motor, in order to detect certain events that occur during the operation of the motor. A calibration method is also disclosed that can account for one or both of the protection circuit and event-detecting controller. The calibration method accounts for human interaction and, in doing so, is intended toward making a calibration process of a motorized household system less prone to human error.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A sensor and control platform includes a smart wall plate and a variety of optional sensor/control elements that removably couple to and interact and communicate with the smart wall plate to enhance the functionality and power of a premises automation system. The smart wall plate contains a plurality of sensors, a microprocessor control unit, and a wireless transceiver. The optional sensor/control elements can be a control dial, a monitoring device, or a camera. The smart wall plate can dictate the functionality of the optional sensor/control elements or the optional sensor/control elements can alter the functionality of the smart wall plate.

Abstract: A commissioning system and method that applies a design configuration, representative of a building automation and control system, to a mesh network of network-capable devices. A cloud-based server system works in concert with an installing device, such as a smartphone or tablet, to apply the relevant configuration of scenarios and spaces, as defined in the design configuration during a design phase, to each mesh node in the mesh network. The commissioning system first transforms the defined scenarios and spaces, which essentially represent a logical configuration of the building automation and control system, into a network-centric configuration. Then, the system decomposes the network-centric configuration into a physical configuration of each mesh node, resulting in a set of parameters for each mesh node. The commissioning system then transmits the set of parameters, including one or more group addresses, to the applicable mesh node, for each affected mesh node in the network.

Abstract: A system and method involving actor nodes within a building that is being controlled, to be subscribed to a set of addresses, including one or more addresses that are representative of one or more respective spaces within the building being controlled. Such addresses are referred to as “space addresses.” Each of the actor nodes acts upon received data packets only if a space address is received along with the data packets and the actor node has been subscribed to the space address. Concurrently, one or more sensor nodes in the system are configurable to transmit the one or more space addresses and the data packets. A user device in the system receives commands from a user via a user interface and transmits a set of signals such that the actor nodes are subscribed to the appropriate space addresses and the sensor nodes are configured to transmit the space addresses.

Abstract: A motorized system that allows for calibration by a user, and that features circuit protection and detection of motor stoppage. A motorized window-blind system is an example of such a system and is disclosed herein. In particular, a circuit is featured that comprises a TRIAC, or “triode for alternating current,” and TVS diodes, or “transient-voltage-suppression diodes,” providing voltage protection to various types of motor-related electronic components. A controller is disclosed that features measurement of voltage that is induced on a secondary winding of a motor, in order to detect certain events that occur during the operation of the motor. A calibration method is also disclosed that can account for one or both of the protection circuit and event-detecting controller. The calibration method accounts for human interaction and, in doing so, is intended toward making a calibration process of a motorized household system less prone to human error.

Abstract: A motorized system that allows for calibration by a user, and that features circuit protection and detection of motor stoppage. A motorized window-blind system is an example of such a system and is disclosed herein. In particular, a circuit is featured that comprises a TRIAC, or “triode for alternating current,” and TVS diodes, or “transient-voltage-suppression diodes,” providing voltage protection to various types of motor-related electronic components. A controller is disclosed that features measurement of voltage that is induced on a secondary winding of a motor, in order to detect certain events that occur during the operation of the motor. A calibration method is also disclosed that can account for one or both of the protection circuit and event-detecting controller. The calibration method accounts for human interaction and, in doing so, is intended toward making a calibration process of a motorized household system less prone to human error.

Abstract: The product unit disclosed herein has identification data that are stored internally in memory. This stored identification data can be viewed as the product unit's “digital nameplate,” in that the data can represent the product unit's identifier, brand, and so on. Each data set is digitally signed while on the production line by using an encryption technique. The digitally signed data set is then written into the product unit's memory where it can be used for verification. A first digitally-signed data set can be used to control the use of one or more software modules that are provided by a software owner. The data that are undergoing signature contain at least one globally-unique identifier, which can be used to identify cloning attempts. Additionally, more than one digital signature can be used, in order to protect and control the use of features other than the software, such as the product brand.

Abstract: A monitoring device for use in an automation system, such as for a home, warehouse, or any type of structure. The monitoring device includes sensors, a processor, and a transmitter. Using its sensors, the monitoring device is capable of acquiring data about itself and/or its environment. That data is used by the monitoring device and/or a central controller to generate a request for an actor, such as lighting, an HVAC system, motorized drapes, a home entertainment system, other home systems, or appliances, to change its state.