Abstract: Techniques for synchronizing superframes across apparatuses are disclosed. An apparatus for communication with a plurality of devices is set to a premise communication mode. While in the premise communication mode, the apparatus outputs a first superframe configured in a premise communication superframe mode allocating each slot of a plurality of slots for wireless communication to a first protocol at a first frequency band or a different second protocol. The apparatus transitions from the premise communication mode to a community communication mode. While in the community communication mode, the apparatus outputs a second superframe configured in a community communication superframe mode allocating at least one slot for wireless communication to the first protocol or the second protocol at the first frequency band, and at least one slot for wireless communication to a community beacon including data relating to a unique key recognizable by a remote apparatus.

Abstract: A system includes a controller, a heating, ventilation, and air conditioning (HVAC) unit, first and second dampers, and first and second pressure sensors. The first damper is positioned at a first air duct that supplies air from an exterior of a premises. The second damper is positioned at a second air duct that supplies air from an interior of the premises. The first pressure sensor is configured to detect an air pressure exterior to the premises. The second pressure sensor is configured to detect an air pressure within the premises. The controller is configured to receive the detected exterior air pressure and the detected interior air pressure, and the controller is configured to change the air pressure within the premises by adjusting at least one of the first damper and the second damper based on the detected exterior and interior air pressures.

Abstract: A system includes a sensor device, a hub device, and a keypad device. The keypad device is configured to operate in a keypad mode and a wireless repeater mode. In the wireless repeater mode, the keypad device is in communication with the hub device and in direct communication with the sensor device such that the keypad device, in the wireless repeater mode, acts as a wireless repeater between the hub device and the sensor device.

Abstract: A system includes a controller, a heating, ventilation, and air conditioning (HVAC) unit, first and second dampers, and first and second pressure sensors. The first damper is positioned at a first air duct that supplies air from an exterior of a premises. The second damper is positioned at a second air duct that supplies air from an interior of the premises. The first pressure sensor is configured to detect an air pressure exterior to the premises. The second pressure sensor is configured to detect an air pressure within the premises. The controller is configured to receive the detected exterior air pressure and the detected interior air pressure, and the controller is configured to change the air pressure within the premises by adjusting at least one of the first damper and the second damper based on the detected exterior and interior air pressures.

Abstract: A system includes a sensor device, a hub device, and a keypad device. The keypad device is configured to operate in a keypad mode and a wireless repeater mode. In the wireless repeater mode, the keypad device is in communication with the hub device and in direct communication with the sensor device such that the keypad device, in the wireless repeater mode, acts as a wireless repeater between the hub device and the sensor device.

Abstract: In some examples, a method includes receiving, from a carbon-monoxide (CO) sensor, an indication of an above-threshold level of CO for an above-threshold amount of time; determining, from a plurality of appliances, a subset of appliances associated with the CO sensor; and deactivating the subset of appliances.

Abstract: A system includes a sensor device, a hub device, and a keypad device. The hub device is in communication with the sensor device using time divisional multiple access (TDMA) The keypad device is in communication with the hub device. The keypad device is configured to operate in: a keypad mode and a wireless repeater mode. In the keypad mode, the keypad device is in communication with the hub device but not in direct communication with the sensor device. In the wireless repeater mode, the keypad device is in communication with the hub device and in direct communication with the sensor device using TDMA such that the keypad device, in the wireless repeater mode, acts as a wireless repeater between the hub device and the sensor device.

Abstract: A premises communication hub includes a primary communications module, a secondary communications module, a power supply, and a charging module. The primary communications module is configured to receive a premises signal from a premises device and transmit an external signal to a remote server. The secondary communications module is configured to receive the premises signal from the premises device and transmit the external signal to the remote server. The power supply includes a primary power input configured to receive power from a primary power source and a secondary power input configured to receive power from a secondary power source. The power supply is electrically connected to the primary communications module and the secondary communications module. And, the charging module is electrically connected to the secondary power source and configured to recharge the secondary power source.

Abstract: A system includes a sensor device, a hub device, and a keypad device. The hub device is in communication with the sensor device using time divisional multiple access (TDMA) The keypad device is in communication with the hub device. The keypad device is configured to operate in: a keypad mode and a wireless repeater mode. In the keypad mode, the keypad device is in communication with the hub device but not in direct communication with the sensor device. In the wireless repeater mode, the keypad device is in communication with the hub device and in direct communication with the sensor device using TDMA such that the keypad device, in the wireless repeater mode, acts as a wireless repeater between the hub device and the sensor device.

Abstract: A sensor device includes processing circuitry configured to output, at a first bandwidth, first bandwidth data to a hub device using a first wireless connection configured for a first wireless protocol. In response to determining that the sensor device has second bandwidth data to output to the hub device at a second bandwidth, the processing circuitry is configured to output a second wireless connection request to the hub device using the first wireless connection. In response to the hub device outputting information for establishing a second wireless connection with the sensor device, the processing circuitry is configured to establish the second wireless connection for a second wireless protocol different from the first wireless protocol. The processing circuitry is configured to output, at the second bandwidth, the second bandwidth data to the hub device using the second wireless connection. The second bandwidth is greater than the first bandwidth.

Abstract: A premises communication hub includes a primary communications module, a secondary communications module, a power supply, and a charging module. The primary communications module is configured to receive a premises signal from a premises device and transmit an external signal to a remote server. The secondary communications module is configured to receive the premises signal from the premises device and transmit the external signal to the remote server. The power supply includes a primary power input configured to receive power from a primary power source and a secondary power input configured to receive power from a secondary power source. The power supply is electrically connected to the primary communications module and the secondary communications module. And, the charging module is electrically connected to the secondary power source and configured to recharge the secondary power source.

Abstract: A sensor device includes processing circuitry configured to output, at a first bandwidth, first bandwidth data to a hub device using a first wireless connection configured for a first wireless protocol. In response to determining that the sensor device has second bandwidth data to output to the hub device at a second bandwidth, the processing circuitry is configured to output a second wireless connection request to the hub device using the first wireless connection. In response to the hub device outputting information for establishing a second wireless connection with the sensor device, the processing circuitry is configured to establish the second wireless connection for a second wireless protocol different from the first wireless protocol. The processing circuitry is configured to output, at the second bandwidth, the second bandwidth data to the hub device using the second wireless connection. The second bandwidth is greater than the first bandwidth.

Abstract: In some examples, a method includes receiving, from a carbon-monoxide (CO) sensor, an indication of an above-threshold level of CO for an above-threshold amount of time; determining, from a plurality of appliances, a subset of appliances associated with the CO sensor; and deactivating the subset of appliances.

Abstract: Some methods for detecting and avoiding radio interference in a wireless sensor network can include an access point device periodically transmitting a beacon message to a plurality of IoT enabled devices via a radio channel, upon receipt of the beacon message, an IoT enabled device attempting to decode the beacon message, the IoT enabled device measuring and storing a signal strength of a successfully decoded beacon message as signal strength data in a memory of the IoT enabled device, the IoT enabled device increasing a missed beacon counter stored in the memory of the IoT enabled device responsive to a beacon message that cannot be decoded, each of the plurality of IoT enabled devices periodically transmitting stored data to the access point device, and the access point device using the received data to identify an interference source, or an interference issue or a fading issue on the radio channel.

Abstract: Systems and methods are provided that include an access point receiving a request from a device to join a first network defined by a first protocol, the access point allocating a slot of a superframe to the device, and the access point allocating remaining slots of the superframe to communication by the access point on a second network defined by a second protocol. Additionally or alternatively, some methods can include the access point enabling a first transceiver communicating via the first protocol and either, when the first transceiver receives first data from the device via the first protocol within a predetermined time of a beginning of the slot, receiving second data from the device via the first protocol for a remainder of the slot or, when the first transceiver module fails to receive the first data, the access point enabling a second transceiver for the remainder of the slot.

Abstract: Systems and methods of a portable device roaming between a plurality of access point devices with which the portable device is enrolled are provided. Some methods can include the portable device saving a respective network parameter of each of the plurality of access point devices, the portable device traversing a plurality of channels in which the plurality of access point devices operate, the portable device operating in a respective one of the plurality of channels to receive a packet from a respective one of the plurality of access point devices, the portable device comparing a received network identifier in the packet with the respective network parameter of each of the plurality of access point devices as saved, and responsive to a match, the portable device transmitting a command signal to the respective one of the plurality of access point devices.

Abstract: Some methods for detecting and avoiding radio interference in a wireless sensor network can include an access point device periodically transmitting a beacon message to a plurality of IoT enabled devices via a radio channel, upon receipt of the beacon message, an IoT enabled device attempting to decode the beacon message, the IoT enabled device measuring and storing a signal strength of a successfully decoded beacon message as signal strength data in a memory of the IoT enabled device, the IoT enabled device increasing a missed beacon counter stored in the memory of the IoT enabled device responsive to a beacon message that cannot be decoded, each of the plurality of IoT enabled devices periodically transmitting stored data to the access point device, and the access point device using the received data to identify an interference source, or an interference issue or a fading issue on the radio channel.

Abstract: Systems and methods for synchronizing wireless sensor devices connected to a control panel device via multiple access point devices are provided. Some methods can include a control panel device periodically transmitting a time signal to an access point device, the access point device periodically receiving the time signal from the control panel device and using the time signal to synchronize with the control panel device, the access point device periodically transmitting a wireless beacon that includes a timestamp of the access point device to a sensor device, and the sensor device periodically exiting a sleep mode to receive the wireless beacon from the access point device and using the timestamp to synchronize with the access point device.

Abstract: Some methods for detecting and avoiding radio interference in a wireless sensor network can include an access point device periodically transmitting a beacon message to a plurality of IoT enabled devices via a radio channel, upon receipt of the beacon message, an IoT enabled device attempting to decode the beacon message, the IoT enabled device measuring and storing a signal strength of a successfully decoded beacon message as signal strength data in a memory of the IoT enabled device, the IoT enabled device increasing a missed beacon counter stored in the memory of the IoT enabled device responsive to a beacon message that cannot be decoded, each of the plurality of IoT enabled devices periodically transmitting stored data to the access point device, and the access point device using the received data to identify an interference source, or an interference issue or a fading issue on the radio channel.

Abstract: Systems and methods of a portable device roaming between a plurality of access point devices with which the portable device is enrolled are provided. Some methods can include the portable device saving a respective network parameter of each of the plurality of access point devices, the portable device traversing a plurality of channels in which the plurality of access point devices operate, the portable device operating in a respective one of the plurality of channels to receive a packet from a respective one of the plurality of access point devices, the portable device comparing a received network identifier in the packet with the respective network parameter of each of the plurality of access point devices as saved, and responsive to a match, the portable device transmitting a command signal to the respective one of the plurality of access point devices.