A microcontroller configured to monitor the input voltage and load conditions, and continuously adjust the switching frequencies in order to optimize the efficiency and longevity of the power supply incorporated in a device. The microcontroller utilizes a combination of GaN switching elements with their efficient high frequency switching capabilities, together with the continuous monitoring of the load conditions, allowing the intelligent microcontroller to vary the switching frequency of the power conversion blocks as needed in order to maintain the highest efficiency of conversion. The microcontroller can be utilized to control a luminaire or other device into which the controller is preferably integrated. The microcontroller can utilize one or more environmental sensors configured for sensing internal environmental conditions and/or external environmental conditions. Preferably the microcontroller utilizes an energy storage device configured to power the microcontroller and associated sensors to allow the mesh network controls to continue functioning in the event of a power outage.

A method for communicating includes transmitting a code to a first device via a first network. The code is configured to execute on a virtual environment associated with the first device. When executed on the virtual environment, the code causes the first device to communicate with a second device via a second network. The first network is based on a first network protocol, and the second network is based on a second network protocol different from the first network protocol.

A method of remotely configuring access to at least one home automation device that is part of a home-automation installation, the home automation installation comprising at least one home automation device and at least one central control unit, and the method being performed by a first remote access service carried out by a management unit and including the following steps: receiving an information message relating to the presence of the home automation device from a central control unit to which the device is linked; determining a second service associated with the type of home automation device for which remote access must be configured with corresponding access rules; configuring an access rights reference system in order to accept at least one control command from the second service or transmitting monitoring data to the second service on behalf of the home automation device. The present application also relates to a control and monitoring method.

A system and method are provided for controlling operations of devices in an IoT environment based on a correlation between devices. The controlled operations include identifying a first device in response to a user pointing the electronic device toward the first device, determining at least one second device contextually related to the first device, and recommending at least one suggestion to control at least one operation of at least one of the first device or the at least one second device, based on a correlation between capabilities of the first device and a current operating context of the at least one second device.

A system and method are provided for controlling operations of devices in an IoT environment based on a correlation between devices. The controlled operations include identifying a first device in response to a user pointing the electronic device toward the first device, determining at least one second device contextually related to the first device, and recommending at least one suggestion to control at least one operation of at least one of the first device or the at least one second device, based on a correlation between capabilities of the first device and a current operating context of the at least one second device.

The present technology relates to an information processing apparatus and an information processing method that enable a base station to appropriately determine a terminal in charge of receiving processing. Priority of a base station in charge of receiving processing of the terminal among base stations that have received a connection request from the terminal is set for each of a plurality of terminals, and a charged terminal in charge of the receiving processing is determined for each of a plurality of base stations according to the priority of the base station. The present technology can be applied to, for example, a wireless communication system in which a terminal and a base station perform wireless communication.

The present technology relates to an information processing apparatus and an information processing method that enable a base station to appropriately determine a terminal in charge of receiving processing. Priority of a base station in charge of receiving processing of the terminal among base stations that have received a connection request from the terminal is set for each of a plurality of terminals, and a charged terminal in charge of the receiving processing is determined for each of a plurality of base stations according to the priority of the base station. The present technology can be applied to, for example, a wireless communication system in which a terminal and a base station perform wireless communication.

The present disclosure relates to systems and methods for providing cybersecurity functionality to computer implemented inventions such as Internet of Thing (IoT) systems and object devices, and more specifically, to an improved cybersecurity system, method and capabilities for the protecting IoT and similar devices through non-discriminatory vendor/supplier independent distribution of secure predetermined IoT syndication data to unidentified and non-registered IoT devices, through the use of a passive data distribution technology and out-of-band, system-to-device distribution channel and no peer-to-peer stateless relationship with the receiving device and using Quality of Service (QoS) and enabling the determination as to whether there is any suspicious activity occurring and prohibiting the IoT device from taking any customer-defined action without have a separately provided authentication.

Systems and methods of dynamic IoT device regulation and control can aid in shifting a user's emotional state from a first state of mind to a preferred second state of mind, using the user's biomarker response to device settings. Particularly, an IoT device controller may be embedded within a wearable device that is wirelessly connected to a computing device and one or more IoT devices. Initially, each wearable device can be calibrated, wherein a matrix of sensed user biomarker responses can be generated. In some embodiments, the system continuously monitors user biomarkers to detect which physiological state exists. When the user enters into the first physiological/psychological state, the system can adjust each IoT device to align with the second state. When the system detects that the user biomarker response has not shifted, the system can continuously adjust IoT settings based upon a learning algorithm having monitored user biomarkers as input.

Systems and methods of dynamic IoT device regulation and control can aid in shifting a user's emotional state from a first state of mind to a preferred second state of mind, using the user's biomarker response to device settings. Particularly, an IoT device controller may be embedded within a wearable device that is wirelessly connected to a computing device and one or more IoT devices. Initially, each wearable device can be calibrated, wherein a matrix of sensed user biomarker responses can be generated. In some embodiments, the system continuously monitors user biomarkers to detect which physiological state exists. When the user enters into the first physiological/psychological state, the system can adjust each IoT device to align with the second state. When the system detects that the user biomarker response has not shifted, the system can continuously adjust IoT settings based upon a learning algorithm having monitored user biomarkers as input.