A monitoring system includes one or more sensors, one or more connected electronic, and a monitor control unit that is configured to receive sensor data from the one or more sensors, determine usage data that reflects a level of usage of the one or more connected electronic devices, receive occupancy data that reflects an occupancy level of the property, train a predictive model that is configured to determine a likely occupancy level of the property, receive, at a current time and from the one or more sensors, current sensor data, determine, at the current time, current usage data that reflects a current level of usage of the one or more connected electronic devices, apply the current usage data and the current sensor data to the predictive model, determine a likely current occupancy level of the property, determine that the likely current occupancy level of the property is unexpected, and perform an action.

In order to be able to realistically display and imitate the presence of humans and/or animals in a building with simple, inexpensive means, it is provided that the intensity of the radiated light of at least one group of adjacent light sources is reduced relative to the intensity of the radiated light from light sources of the arrangement outside of the at least one group in order to imitate a shadow on a wall illuminated by the security device and further light sources are added to at least one group and/or light sources of the at least one group are removed from the same and the intensity of the radiated light of an added light source is reduced and the intensity of a remote light source is increased in order to imitate a movement of the shadow.

A computer-implemented method for remote presence security is described. In one embodiment, an event is detected in relation to a premises. Upon detecting the event, a location of an occupant of the premises is determined in relation to the premises. Upon determining the occupant is a predetermined distance away from the premises, a first type of notification is sent. The first type of notification includes a display of real-time video being captured at the premises.

Systems and methods for sharing of video footage from audio/video (A/V) recording and communication devices to smart television (TV) devices in accordance with various embodiments of the present disclosure are provided. In one embodiment, a method for playing back video footage captured by A/V recording and communication devices located in a plurality of neighborhoods, using a smart TV, is provided, the method comprising: connecting the smart TV to a neighborhood subscriber channel; subscribing to a first channel of the neighborhood subscriber channel, wherein the first channel is associated with a first neighborhood of the plurality of neighborhoods; receiving a list of available content shared with the first neighborhood, wherein the available content shared with the first neighborhood includes first image data captured using a camera of a first A/V recording and communication device; and selecting and playing back, on the smart TV, the first image data.

The various implementations described herein include methods, devices, and systems for monitoring activity in a home environment. In one aspect, a method performed at a voice-assistant device includes: detecting a sound; obtaining a determination as to whether the sound meets one or more monitoring criteria; and in accordance with a determination that the sound meets the one or more monitoring criteria, generating a notification.

A lifestyle LED security light including a light-emitting unit configured with two sets of LED loads respectively emitting different color temperature lights is disclosed. At dusk the light-emitting unit is automatically turned on for a first level illumination with a low color temperature light featuring an aesthetic night view with the motion sensor being deactivated for a time duration, and then the light emitting unit is changed to a second level illumination and at the same time the motion sensor is activated, wherein when the motion sensor detects a motion intrusion, the light-emitting unit is instantly switched to perform a third level illumination with a a high light intensity and a high color temperature light. The color temperatures of the first level illumination and the third level illumination are respectively adjustable by simultaneously and reversely adjusting the electric powers respectively allocated to the two sets of LED loads.

An electronic visible light sensor is employed to detect the presence or lack of sunlight. The simple, digital light/dark data from the sensor is fed to electronic circuits which control security and other devices dependent upon day and night status. These circuits are directed and controlled in turn by associated electronic circuits that gather data which measures the length of the solar night, that is, between dusk and dawn, and by deduction, the length of the day. Given that these time periods vary daily and in a regular fashion, the result will necessarily differ by a few minutes each and every day during the 365 day solar year. The resulting day/night time data is used to estimate, with say, a four to ten minute accuracy, taken against the Universal Coordinated Time System, to establish start/stop times, durations and cycles of security and other devices dependent upon the presence or lack of sunlight relative to UCT designated within the universally accepted twenty-four day. These results are fed to the security control circuitry to define control of data to security and other devices.

This patent specification relates to apparatus, systems, methods, and related computer program products for providing home security/smart home objectives. More particularly, this patent specification relates to a plurality of devices, including intelligent, multi-sensing, network-connected devices, that communicate with each other and/or with a central server or a cloud-computing system to provide any of a variety of useful home security/smart home objectives.

Methods, systems and computing devices are described herein for monitoring a premises when residents or other users are present in order to detect patterns of activity at the premises. Such patterns may comprise, for example, a typical schedule indicating usage of one or more devices by one or more users of the premises. When a user is away or otherwise inactive, commands may be sent to various user devices to make it appear (e.g., to those outside the premises) as if the user is present by simulating and/or recreating the patterns that were previously detected.

A method (100) for controlling a plurality of devices (10) of a smart home system (20) is provided. The method (100) comprises: switching (S110) the smart home system (20) between a home mode (21) and an away mode (22); and upon the smart home system (20) being in the away mode (22), independently controlling (S140) a setting of each of the plurality of devices (10) based on a usage pattern (12) of the respective device (10); wherein the independently controlling (S140) a setting of each of the plurality of devices (10) comprises: for a specific device (10), determining (S141) a first point in time (31) to change a setting of the device (10) based on the usage pattern (12) of the device (10), wherein the first point in time (31) is limited to: any of a set of predetermined points in time during a day, and a point in time where the smart home system (20) is set in the away mode (22); calculating (S142) a second point in time (32) by adding a random offset in time to the first point in time (31); changing (S143) the setting of the device (10) at the second point in time (32); determining (S144) a stasis period (33) during which the setting of the device (10) should be maintained based on the usage pattern (12) of the device (10); and maintaining (S145) the setting of the device (10) for the stasis period (33). A smart home system (20) is also provided.