The field of the invention relates to security systems and more particularly to wireless security systems.
Security systems are generally known. Such systems typically include some form of physical barrier to intruders with one or more sensors to detect intruders who are able to surmount the barrier.
In the case of a home, the physical barrier may be the exterior walls of the home. In this case, the sensors may include door sensors that detect the opening or closing of the doors. Window sensors may also be provided to detect intruders who attempt to enter through a window.
The sensors within a home are typically electrical switches that are mechanically connected to a door or window. In other cases, motion detectors may be used that are based upon infrared detection or the processing of video signals.
In all cases, the sensors are connected to a control panel. The connection may be via wires or via a radio frequency signal.
The control panel typically operates in three modes including disarmed, armed and armed stay. In the disarmed state, the control panel does not report activation of the sensors, while in the armed state the control panel sounds an alarm and may report the alarm to a central monitoring station. In the armed stay used during night time hours, the control panel may only monitor sensors along a periphery of the home.
While security systems are effective, they are typically used in a stand-alone mode because of the need for reliability. However, homes and businesses often have a multiplicity of systems that must be adjusted or controlled based upon occupancy. Accordingly, there is a continuing need to leverage the utility of signals available within a security system for other purposes.
The panel 16 of the security system 10 includes one or more programmed processors 22, 24 operating under control of computer software (i.e., computer code). The computer code includes a number of programs 32, 34 residing in a non-transitory computer readable medium 30.
The security system 10 includes a number of intrusion sensors 18, 20 within or along a periphery of the secured area 12. The sensors 18, 20 may be electrical switches that detect the opening of a door or window or may be motion detectors that detect motion within the secured area 12. The control panel 16 may communicate with the sensors 18, 20 using wires or may communicate wirelessly.
At least one of the programmed processors 22, 24 operates as a status processor that detects entry of a code through a keyboard 38 of the security system 10 and that causes the alarm system 10 to enter a predefined state based upon the entered code. The entered code may include an alarm-away code defining an alarm-away state, a disarm code defining a disarmed state and an alarm-stay code defining an alarm-stay state. The current state of the alarm panel 16 may be indicated by text shown on a display panel 36.
At least one other of the programmed processors 22, 24 (or one of the programs 32, 34 operating on the same processor) operates as an intrusion detection processor based upon the state of the alarm system 10. For example, the intrusion detection processor may monitor all of the sensors 18, 20 when the alarm system 10 is in the alarm-away state and only the perimeter sensors 18, 20 when the alarm system 10 is in the alarm-stay state.
Another one of the programmed processors 22, 24 (or the same processor) operates as an alarm reporting processor. In this case, whenever the intrusion detection processor detects activation of a monitored sensor 18, 20, the intrusion detection processor transfers notification thereof to the alarm reporting processor. The alarm reporting processor composes an alarm packet for transfer to the central monitoring station 14. After an entry delay, the alarm reporting processor transfers the alarm notification to the central monitoring station 14.
Upon assuming an alarm-away or alarm-stay mode, the control panel 16 may wirelessly transmit a status message 42 to the sensors 18, 20. This status message indicates a status of the alarm panel 16 and requests a status of the respective sensors 18, 20. This may be important because it is necessary to know that the area 12 is secure (i.e., the sensors 18, 20 are not in an activated state) when ever the alarm panel 16 enters the alarm-away or alarm-stay mode. If one of the sensors 18, 20 is in an activated state, then a fault message is returned to the user.
Also included within the secured area 12 are one or more appliance control devices 44, 46. The appliance control devices 44, 46 operate to control an operating level of a respective connected appliance 48, 50.
Included within each of the appliance control devices 44, 46 may be a radio frequency (rf) receiver 52, a decryption unit 54 and a status processor 56. The rf receiver 52 may continuously monitor a transmission spectrum of the security system 10 for status messages 42. Any received messages are processed within the decryption unit 54 to decrypt alarm-away, alarm-stay and disarm messages. Any detected alarm-away and disarm messages are sent to the status processor 56.
Upon receiving an alarm-away message, the status processor 56 sends a command to any connected appliance 48, 50 to switch to a relatively low power mode. Upon receiving a disarm message, the status processor 56 sends a command to any connected appliance 48, 50 to switch to a normal mode of operation. Stated another way, the appliance control device 44, 46 has an ON and OFF output, the appliance control device 44, 46 provides one of the ON and OFF outputs upon receiving the armed status message from the security system and the other of the ON and OFF outputs upon receiving the disarmed status message.
The appliances 48, 50 may be any appropriate environmental control device within the secured area 12. For example, the appliance 48, 50 may be an air conditioner used to cool or a heating unit used to heat the area 12. Alternatively, the appliance 48, 50 may be a ceiling fan or motor operate shade or window that obstructs or opens a window to controls the amount of heat or cooling that the space obtains via sunlight or the exchange of inside/outside air.
Moreover, the appliance 48, 50 may be an interface device that causes the environmental control device to operate between a relatively low power consumption mode to a relatively high power mode. An example of such an interface device is a set-back thermostat or active solar heating/cooling system.
In general, the appliance control device operates to detect the status of the alarm system 10 and, in response, to cause the appliance to switch between the relatively low power consumption mode and relatively high power mode. For example, an occupant (e.g., a homeowner) may enter an alarm-away code into his security system 10, when the occupant is about to leave the area 12 for some period of time. Entry of the alarm-away code through the keyboard 38 causes the alarm panel 16 to transmit an encrypted alarm-away message 42 to the sensors 18, 20. The message 42 causes the sensors 18, 20 to respond with an encrypted message indicating their status (e.g., activated, deactivated, etc.).
Under the claimed invention, this encrypted status message is used to control the state of the appliances 48, 50. For example, on a day where the outside temperature is 90 degrees, the receipt of the alarm-away status message 42 may cause the applicant controller 44, 46 to cause the air conditioner to switch from a set point temperature of 75 degrees to 85 degrees or higher resulting in a substantial energy savings.
The appliance control devices 44, 46 may be provided in any of a number of different forms depending upon the format of use. For example, the appliance control device 44, 46 may be incorporated or integrated into the control system of a ceiling fan or light switch. In either case, receipt of an alarm-away message may cause the fan to become deactivated or to transcend to a very low power mode.
Alternatively, the appliance control device 44, 46 may be provided as a separate control module with a set of contacts or with a standardized bus interface (e.g., USB, PCI, etc.) or wireless interface (e.g., Zigbee). In this case, the control module may be connected to an air conditioner control input to cause the air conditioner to transition to the appropriate mode.
A specific embodiment of method and apparatus for controlling appliances in a secured area has been described for the purpose of illustrating the manner in which the invention is made and used. It should be understood that the implementation of other variations and modifications of the invention and its various aspects will be apparent to one skilled in the art, and that the invention is not limited by the specific embodiments described. Therefore, it is contemplated to cover the present invention and any and all modifications, variations, or equivalents that fall within the true spirit and scope of the basic underlying principles disclosed and claimed herein.
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European Search Report, dated Mar. 16, 2012, corresponding to Application No. EP 11 19 0024. |
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20120126935 A1 | May 2012 | US |