A heating, ventilation and air condition (HVAC) system is provided. The system includes a thermostat including an onboard temperature sensor, a remote temperature sensor in operable communication with the thermostat, and a controller in operable communication with each of the onboard sensor and the remote sensor and configured to execute a control algorithm that calculates a temperature difference between a temperature detected by the onboard temperature sensor and a temperature detected by the remote temperature sensor, such that when the remote temperature sensor fails, the controller uses the calculated temperature difference to calibrate the onboard temperature sensor and set the thermostat to the temperature detected by the remote temperature sensor.

A sensor for sensing environmental characteristics of a space may include a visible light sensing circuit for recording an image of the space and a control circuit responsive to the visible light sensing circuit. The control circuit may detect an occupancy or vacancy condition in the space in response to the visible light sensing circuit, and measure a light level in the space in response to the visible light sensing circuit. The control circuit may also include a low-energy occupancy sensing circuit for detecting an occupancy condition in the space. The control circuit may disable the visible light sensing circuit when the space is vacant. The control circuit may detect an occupancy condition in the space in response to the low-energy occupancy sensing circuit and subsequently enable the visible light sensing circuit. The visible light sensor may be configured in a way that protects the privacy of the occupants of the space.

A sensor for sensing environmental characteristics of a space may include a visible light sensing circuit for recording an image of the space and a control circuit responsive to the visible light sensing circuit. The control circuit may detect an occupancy or vacancy condition in the space in response to the visible light sensing circuit, and measure a light level in the space in response to the visible light sensing circuit. The control circuit may also include a low-energy occupancy sensing circuit for detecting an occupancy condition in the space. The control circuit may disable the visible light sensing circuit when the space is vacant. The control circuit may detect an occupancy condition in the space in response to the low-energy occupancy sensing circuit and subsequently enable the visible light sensing circuit. The visible light sensor may be configured in a way that protects the privacy of the occupants of the space.

The present invention provides a touch-type control system, a control device and a monitor device for merchandise security, including a controller and a monitor device, where the monitor device has an identifiable communication interface capable of communicating with the controller, and is configured to communicate with the controller via the identifiable communication interface and be initialized by a controller in communication therewith. The controller further comprises a touch-type communication interface for communicating with the monitor device, and is configured to be capable of controlling the monitor device initialized by the controller via the touch-type communication interface. In the system, the controller can communicate with the monitor device by means of a touch manner, thereby identifying, controlling and powering the monitor device, thereby solving the problem of the unification of power supply and data in the system.

The invention provides a grading control system and a control device for merchandise security, including at least two controllers and a plurality of monitor devices, wherein the controller comprises at least one main controller and at least one auxiliary controller. The monitor device has an identifiable communication interface that is capable of communicating with the controller, and is configured to be communicable with the controller via the identifiable communication interface, and to be initialized by the controller in communication therewith. The monitor device initialized by the auxiliary controller can be controlled by the main controller and the auxiliary controller. In this system, the controller can control the monitor devices within a set range according to the different privilege/level settings, respectively. The range controlled by the controller in the same system may be divided into different grades of control, realizing the control of grading and sub-regions and reflecting grading management.

The invention provides a grading control system and a control device for merchandise security, including at least two controllers and a plurality of monitor devices, wherein the controller comprises at least one main controller and at least one auxiliary controller. The monitor device has an identifiable communication interface that is capable of communicating with the controller, and is configured to be communicable with the controller via the identifiable communication interface, and to be initialized by the controller in communication therewith. The monitor device initialized by the auxiliary controller can be controlled by the main controller and the auxiliary controller. In this system, the controller can control the monitor devices within a set range according to the different privilege/level settings, respectively. The range controlled by the controller in the same system may be divided into different grades of control, realizing the control of grading and sub-regions and reflecting grading management.

Methods and systems for e-commerce fulfillment is disclosed. The method includes sending instruction to product feeder to receive a plurality of products. The method includes sending instruction to product feeder to place each product of plurality of products on a conveyor belt after receiving plurality of products. The method includes receiving product barcode information associated with each product of plurality of products from a barcode scanner. The method includes receiving sales data associated with each product based on product barcode information associated with each product. The method includes computing a return on investment (ROI) associated with each product based on a product value of each product obtained from sales data. The method further includes sending an instruction to conveyor belt to channelize product in a first conveyor path of conveyor belt if ROI of a product of plurality of products is more than or equal to a threshold ROI.

Methods and systems for e-commerce fulfillment is disclosed. The method includes sending instruction to product feeder to receive a plurality of products. The method includes sending instruction to product feeder to place each product of plurality of products on a conveyor belt after receiving plurality of products. The method includes receiving product barcode information associated with each product of plurality of products from a barcode scanner. The method includes receiving sales data associated with each product based on product barcode information associated with each product. The method includes computing a return on investment (ROI) associated with each product based on a product value of each product obtained from sales data. The method further includes sending an instruction to conveyor belt to channelize product in a first conveyor path of conveyor belt if ROI of a product of plurality of products is more than or equal to a threshold ROI.

A system for a plurality of thermostats each located in a different building in a neighborhood. Each thermostat includes a processing circuit configured to receive one or more assigned operating time slots from an analytics service and operate building equipment associated with the thermostat based on the one or more assigned operating time slots. The system further includes the analytics service. The analytics service includes a processing circuit configured to receive weather forecast data from a weather service and predict a period of time during which an energy usage peak will occur for the plurality of buildings based on the weather forecast data, determine the one or more operating time slots based on the period of time, assign the one or more operating time slots to each of the plurality of thermostats, and send the one or more assigned operating time slots to the plurality of thermostats.

A system for a plurality of thermostats each located in a different building in a neighborhood. Each thermostat includes a processing circuit configured to receive one or more assigned operating time slots from an analytics service and operate building equipment associated with the thermostat based on the one or more assigned operating time slots. The system further includes the analytics service. The analytics service includes a processing circuit configured to receive weather forecast data from a weather service and predict a period of time during which an energy usage peak will occur for the plurality of buildings based on the weather forecast data, determine the one or more operating time slots based on the period of time, assign the one or more operating time slots to each of the plurality of thermostats, and send the one or more assigned operating time slots to the plurality of thermostats.