SENSOR HAVING AN INTEGRATED ZIGBEE® DEVICE FOR COMMUNICATION WITH ZIGBEE® ENABLED APPLIANCES TO CONTROL AND MONITOR ZIGBEE® ENABLED APPLIANCES

Abstract
A sensor device integrates ZigBee® technology into power switch device to provide monitoring and control of power usage, as well as operational control of connected devices. The sensor device uses a power line communication (PLC) network to transfer collected data and to provide remote control capability to connected appliances. The sensor device, in conjunction with a master switch device, a communication enabled switching device, and the power switch device, provides an integrated home environment for communication, streaming media, monitoring, and remote control of power usage, as well as remote operational monitoring and control of connected appliances in the home.
Description
BACKGROUND OF THE INVENTION

1. Technical Field


The invention relates to interfacing ZigBee® technology with power line networking that is enabled for communication and media streaming for remote monitoring and control of utilities such as power, gas, and water. More particularly, the invention relates to a sensor having an integrated Zigbee® device for communication with Zigbee® enabled appliances to control and monitor Zigbee® enabled appliances.


2. Description of the Background Art


Communications via power lines has been known from early in the 20th century. Due to its higher costs and other limitations for extending connectivity, the use of power line communication (PLC) systems has been limited to local area networks (LANs) within homes or offices or, at best, within apartment complexes. PLC has also found a limited number of applications where other types of communication methods do not provide the security and remote connectivity, such as for power line control applications. Basic devices for connecting to the power line for communication and power supply have been designed and used to provide service within LANs. Due to more efficient competing technologies, the infrastructure for PLC never developed to make it a mainstream technology. As a result, more advanced devices for communication using the PLC technology also were never developed.


It is advantageous to identify applications where PLC technology can be optimally used and to develop devices and systems to cater to such applications. One such application that is emerging is in connection with the collection of information and the provision of remote control capability for appliances to reduce the carbon footprint of the home. If this emerging application can simultaneously provide a local area network capability that caters to the needs of communication and streaming media delivery within a home or office, it would be an optimum application for PLC technology. While this is a promising application for the future growth and development of PLC technology, it is still necessary to develop and implement suitable sensor units and systems to meet the needs of this technology and to bring forth its full potential.


SUMMARY OF THE INVENTION

ZigBee® smart energy (www.zigbee.org/) is the world's leading standard for interoperable products that monitor, control, inform, and automate the delivery, control, and use of energy and water. It helps create greener homes by giving consumers the information and automation capability needed to reduce their consumption easily and save money. These products also make it easy for utilities and governments to deploy smart grid solutions that are secure, easy to install, and consumer-friendly. A presently preferred embodiment of the invention combines the residential power monitoring and control capability established using a PLC network with an integrated ZigBee® device to provide a powerful tool for integrated power and operational control of connected appliances in the home or office.


An embodiment of the invention provides a method and apparatus for monitoring and control of power usage, as well as operational control of connected devices. A sensor device integrates ZigBee® technology into the power switch device. The sensor device allows collection and control of the power usage, monitors utilities usage, and controls operation of connected in-home appliances enabled with ZigBee® technology.


In an embodiment, the sensor device uses the PLC network in the home to transfer collected data and to provide remote control capability to connected appliances. The sensor device, in conjunction with a master switch device, a communication enabled switching device, and the power switch device, provides an integrated home environment for communication, streaming media, monitoring, and remote control of power usage, as well as remote operational monitoring and control of connected appliances in the home.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a block schematic diagram of a power switch unit (SW) having broadband information transfer capability;



FIG. 2 is a flowchart showing the collection and transmission of information of power usage of appliance and status of a power plug of an SW unit;



FIG. 3 is a flowchart showing remote control of the power in a power plug of an SW unit;



FIG. 4 is a block schematic diagram of an integrated SW with a ZigBee® enabled (Z-SW) for appliance monitoring, control, and connectivity according to the invention;



FIG. 5 is a block schematic diagram showing a group of appliances whose operation can be monitored and controlled using ZigBee® technology according to the invention;



FIG. 6 is a flowchart showing the collection and transmission operation of operational information using ZigBee® devices on Z-SW from a connected ZigBee® enabled appliance according to the invention;



FIG. 7 is a flowchart showing a control operation using the Z-SW according to the invention; and



FIG. 8 is a block schematic diagram showing a typical PLC network with connected units, some of which are ZigBee® technology enabled using Z-SW according to the invention.





DETAILED DESCRIPTION OF THE INVENTION

ZigBee® smart energy (www.zigbee.org/) is the world's leading standard for interoperable products that monitor, control, inform, and automate the delivery, control, and use of energy and water. It helps create greener homes by giving consumers the information and automation capability needed to reduce their consumption easily and save money. These products also make it easy for utilities and governments to deploy smart grid solutions that are secure, easy to install, and consumer-friendly. A presently preferred embodiment of the invention combines the residential power monitoring and control capability established using a PLC network with an integrated ZigBee® device to provide a powerful tool for integrated power and operational control of connected appliances in the home or office.


An embodiment of the invention provides a method and apparatus for monitoring and control of power usage, as well as operational control of connected devices. A sensor device integrates ZigBee® technology into the power switch device.


The sensor device allows collection and control of the power usage, monitors utilities usage, and controls operation of connected in-home appliances enabled with ZigBee® technology.


In an embodiment, the sensor device uses the PLC network in the home to transfer collected data and to provide remote control capability to connected appliances. The sensor device, in conjunction with a master switch device, a communication enabled switching device, and the power switch device, provides an integrated home environment for communication, streaming media, monitoring, and remote control of power usage, as well as remote operational monitoring and control of connected appliances in the home.


A new sensor device, which integrates ZigBee® technology into the power switch (SW) device is disclosed. The herein disclosed integrated ZigBee® technology enabled power switch (Z-SW) device allows collection and control of the power usage by, and operational control of, connected in-home appliances that have been enabled with ZigBee® technology. The Z-SW device uses the PLC network in the home or office to transfer collected data and to provide remote control capability for power switching, as well as for operation of an appliance connected to the Z-SW device. A Z-SW device, working in conjunction with a master switch (MST) device, a communication enabled switching (ETH) device, and the power switch (SW) device, enables an integrated home environment for communication, streaming media, monitoring, and remote control of power usage, as well as remote operational monitoring with control of the connected appliance in the home or office. Those skilled in the art will appreciate that, while the home and office are discussed herein with regard to application of the herein disclosed invention, other environments may be serviced by the invention as well, and the invention is not limited to only home and office applications.


The development of green technologies and the need for monitoring and control of the carbon footprint of homes and offices has created a need to assess power usage patterns and the magnitude of usage remotely, and to supervise and control the power used by individual appliances remotely. It is advantageous for the consumer to monitor and control power use on a micro level. Providing the proper tools, such as the SW and Z-SW, allows the consumer to exercise the necessary constraints and controls on power use. It is also necessary to monitor the usage pattern and collect data on a macro level to develop policies that are beneficial to the overall reduction of the carbon foot print at the home and office level, as well as on a national level. Empowering the individual and the society to exercise the necessary controls by monitoring and controlling the power usage is an area where the PLC and control can be effectively and optimally used.


An embodiment of the invention, by combining ZigBee® technology into the power switch (SW) device enables the operation of ZigBee® technology enabled intelligent appliances connected to the Z-SW to be controlled via a wireless connection established by the built in ZigBee® device. Further, ZigBee® technology integration into a Z-SW enables monitoring of water, gas, air-conditioning, and security systems within the home or office through the in-built communication channel of the Z-SW. The operational control and monitoring information collected by the built-in ZigBee® functionality is combined with the power usage, monitoring, and control enabled by the SW for connected appliances. This information is transmitted over the in-home PLC network efficiently for any compilation or action required. This above capability is established in addition to the PLC LAN capability made available by use of the communication enabled power monitoring and control device (ETH) and the master unit (MST) described previously in the patent application Ser. No. 13/032,454, which application is incorporated herein in its entirety by this reference thereto.



FIG. 1 is a block schematic diagram of the SW unit 100 without the integrated ZigBee® device. This arrangement allows an appliance in the home or office to be connected to a power supply through the SW device. The SW device provides for the monitoring of power consumption, with the capability for remote control of the power flow to the connected appliance via the Internet. The SW unit 100 has a power plug 103 that is connected to the AC power distribution lines 101 through a power meter and relay 104. The relay in the power meter and relay module 104 provides the capability to switch on or switch off the supply to the power plug 103 remotely. It also allows for controlling the power supplied to the plug when a power control module is included in the power meter and relay module 104. The power meter in the power meter and relay module 104 monitors the power usage by the appliances connected to the power plug. The power meter and relay module 104 is connected via bi-directional communication links 106 to a microcontroller (MCU) 107, for example a microcontroller similar to an Intel® 8051. The microcontroller accepts the information on power usage and compiles it prior to transfer to the broadband communication module 109. The power meter in the power meter and relay module 104 continuously monitors the flow of power to the power plug 103 and feeds the information to the MCU 107 through the communication links 106. The power usage information is compiled by the MCU 107 and sent to a broadband communication module 109 via communication links 108 connected to a UART enabled port on the communication module 109.


In FIG. 1, the communication module 109 modulates the received information to a communication data stream for transmission over a broadband communication frequency band that is typically used for PLC over the AC power distribution lines within a local area network (LAN). The typical broadband used for PLC communication band in the 2 to 30 MHz range provides an up to 200 Mbps data rate. The communication module 109 sends out the modulated data stream over broadband connection 110 to a coupler filter 111 which is connected to the AC power distribution lines 101 by power line connections 112. The coupler filter acts as a bi-directional high pass filter to filter out power line frequency from the communication module. The broadband communication module 109 also demodulates the communication stream received over the AC power distribution lines 101 to provide command and control instructions for power control to the MCU 107. The MCU 107 interprets any received command and control instructions and instructs the power meter and relay module 104, thus controlling the power flow to the power plug 103.



FIG. 2 is a flowchart 2000 showing the operation of the SW 100 as it collects and transmits power usage and power plug 103 status information when an appliance is connected to the power plug 103.


An appliance, such as but not limited to, a refrigerator, a washer, or an oven, is connected to the power plug 103 (S2001).


The power plug 103 is enabled when the relay in the power meter and relay module 104 is closed (relay enabled). Power flows from the AC power distribution lines 101 supplying the home or office to the appliance through the power meter and relay module 104 and the noise filter 103a (S2002).


The power meter and relay module 104 monitors the power usage of the appliance by checking the power flow through the power meter and relay module 104 and the plug 103 (S2003).


The power usage information and the on state or off state of the relay and, hence, power connection are collected by the power meter in the power meter and relay unit 104 (S2004).


This collected information on the status of the power connection is passed on to an MCU 107 for compilation and consolidation (S2005).


The MCU 107 caches the received information. The MCU 107 compiles and consolidates the cached information making it ready for transfer to an MST (S2006).


The prepared information, ready for transfer to a master unit (MST) connected on the power distribution lines 101, is forwarded with the address of the MST to a communication module 109 (S2007).


The communication module 109 receives the information and address of an addressee from the MCU 107. The MCU 107 encrypts the information and combines the encrypted information with the address provided (S2008).


This encrypted information and address are then modulated by the communication module 109. The broadband modulation frequency band used and the type of modulation are as defined in the description of the SW (S2009).


The communication module 109 then sends this modulated information stream onto the AC power distribution lines 101 for transmission to the MST through a coupler filter 111. The filter blocks unwanted frequencies from entering and impacting the operation of the communication module 109 (S2010).



FIG. 3 is a flowchart 3000 showing the operation of a SW 100 unit while providing for remote control of the power flow to an appliance that is connected to the power plug 103. Any information or status changes due to a remote command and control stream are sent back over AC power distribution lines 101 as described in FIG. 3.


The command and control input stream modulated by the correct transmission frequency to control the status and power flow through the SW 100 remotely is delivered over the AC power distribution lines 101 (S3001).


The command and control input stream is passed to the communication module 109 of connected SW 100 through the coupler filter module 111. The communication module 109 demodulates the received command control input stream (S3002).


The addressee of the received demodulated input stream is checked and, if found to be of the specific SW 100, the demodulated input stream is accepted by the SW100 for further processing by the communication module 109 (S3003).


The demodulated command and control stream is decrypted in the communication module 109 to extract the associated command and control inputs for the SW 100 (S3004).


The extracted command and control inputs are passed to the MCU 107 for caching and interpretation (S3005).


The MCU 107 caches the inputs received and interprets them to generate a set of instructions for execution by the power meter and relay module 104. The interpreted instructions include instructions to enable the power flow to the power plug by engaging the relay and to disable the power flow to the power plug by disengaging the relay. If the power meter and relay 104 include power control circuitry, then specific control instructions are provided to the connected appliance on power input (S3006).


The generated instructions are sent to the power meter and relay module 104 of the SW (S3007).


The power meter and relay module 104 receives the instructions sent by the MCU 107 for power flow control to the connected appliance (S3008).


The power meter and relay module 104 acknowledges the instructions from the MCU 107 and executes the instructions received to enable, disable, or otherwise control the power flow to the appliance connected to the power plug 103 (S3009).


The status of the relay and the power usage of the connected power plug 103 are updated on the power meter and relay module 104, and updated power usage and relay status is sent to the MCU 107 for communication back to the initiating remote site (S3010).



FIG. 4 is a block schematic diagram of the Z-SW 400 unit with an integrated ZigBee® device 410. This arrangement allows an appliance in the home or office to be connected to the power supply and PLC link through the Z-SW 400 unit which incorporate a ZigBee® device 410. The Z-SW 400 device monitors power consumption and provides a capability for remote control via the Internet of the power flow to the connected appliance. The ZigBee® device 410 also provides operational control and monitoring through the wireless connection to ZigBee® technology enabled appliances.


The Z-SW unit 400 has a power plug 103 that is connected to the AC power distribution lines 101 through a power meter and relay module 104. The relay in the power meter and relay module 104 provides the capability to switch on or switch off the supply to the power plug 103 remotely. It also allows for controlling the power supplied to the plug when a power control module is included in the power meter and relay module 104. The power meter in the power meter and relay module 104 monitors the power used by the appliances connected to the power plug. The power meter and relay module 104 is connected via bi-directional communication links 106 to a microcontroller (MCU) 107, which can be a microcontroller that is similar to an Intel® 8051. The MCU 107 accepts the information on the power usage from the power meter and relay module 104 and compiles it prior to transfer to the broadband communication module 109. The power meter in the power meter and relay module 104 continuously monitors the flow of power to the power plug 103 and feeds the information to the MCU 107 through the communication links 106. The power usage information is compiled by the MCU 107 and sent to a broadband communication module 109 via communication links 108 that are connected to a UART enabled port on the communication module 109, thus enabling the compiled data to be transmitted out.


The operational commands for the ZigBee® device 410 of the Z-SW 400 are received over the power line and received by the broadband communication module 109 as a data stream. The data stream is demodulated, decrypted, and the resulting data are provided to the MCU 107 over the communication links 109 via the UART enabled port. The MCU 107 converts the data into instructions and passes them on to the ZigBee® device 410 via the bidirectional port 411 over the link 412. Based on received instructions, the ZigBee® device 410 sends out commands to a ZigBee® technology enabled appliance that is connected to the Z-SW 400. The Zigbee® device executes operational commands, for example reading meters, changing temperature settings, etc. The response after the command has been executed is sent back to the ZigBee® device 410 by the ZigBee® technology enabled appliance. The Zigbee® device then converts the response to an information format and passes it on to the MCU 107 via the bidirectional link 412 through the port 411. The MCU collects the information and forwards it, with the address to be responded to, to the broadband communication module 109 via communication links 108 connected to the UART enabled port on the communication module 109.


In FIG. 4, the communication module 109 modulates the received information to a communication data stream for transmission over a broadband communication frequency band that is typically used for PLC over the AC power distribution lines within a LAN. The typical broadband used for PLC communication band in the 2 to 30 MHz range provides an up to 200 Mbps data rate. The communication module 109 sends out the modulated the data stream over broadband connection 110 to a coupler filter 111 which is connected to the AC power distribution lines 101 by power line connections 112. The coupler filter is a bi-directional high pass filter that filters out power line frequency from the communication module. The broadband communication module 109 also demodulates the communication stream received over the AC power distribution lines 101 to provide the command and control instructions for power control and operational control to the MCU 107. The MCU 107 interprets any received command and control instructions to the power meter and instructs the power meter and relay module 104 to control the power flow to the power plug 103 accordingly. The MCU 107 also interprets any operational command and instructions for the ZigBee® device 410 and passes these to the ZigBee® device 410 to be directed to the ZigBee® technology enabled connected appliances.



FIG. 5 is a block schematic diagram that shows typical applications where a ZigBee® technology can provide operational status and control capability within a home or office environment. These applications can include, for example, the monitoring of gas, water, and power usage by providing remote read capability for the utilities, monitoring of security apparatus within the premises, temperature monitoring and control capability, monitoring and control of light fixtures, and monitoring of ZigBee® technology enabled smart appliances within the home.



FIG. 6 is a flow diagram 6000 showing the incoming operational status handling for the ZigBee® device 410 of the Z-SW 400. This operation of the Z-SW 400 is in addition to the power monitoring and control operation of the standard SW unit 100 shown in FIG. 1.


The ZigBee® technology enabled appliance is connected to the power by plugging it into the power plug 103 of the Z-SW 400 unit (S6001).


The built in ZigBee® device 410 on the Z-SW 400 turns on, monitors, and controls the power flow into the ZigBee® technology enabled appliance (S6002).


The ZigBee® device 410 on the Z-SW 400 is linked to the ZigBee® technology enabled connected appliance to establish communication and connection between the Z-SW and the ZigBee® technology enabled appliance (S6003).


Operational information and status of the ZigBee® technology enabled appliance is collected and communicated to the Z-SW 400 through a communication link established between the ZigBee® device 410 on the Z-SW 400 and the ZigBee® technology enabled appliance (S6004).


The received information is passed to the MCU 107 for processing by the ZigBee® device 410 via the communication link connected to the bi-directional port (S6005).


The MCU 107 caches the information received from the ZigBee® device 410 and converts it into the necessary format, including an address for onward transmission to the master unit over the power line (S6006).


The MCU 107 then sends the prepared information with the forwarding addresses to the broadband communication module 109 of the Z-SW 400 over the link 108 connected to the UART on the communication module 109 (S6007).


The communication module 109 encrypts the received information for security where needed (S6008).


The encrypted data is modulated and sent via the coupler filter 111 to the power line network 101 for delivery to the MST for necessary action, including onward transmission to the addressee over the Internet where necessary (S6009).



FIG. 7 is a flowchart showing the handling of the remote operational control instructions sent to a connected ZigBee® technology enabled appliance connected to a Z-SW 400 unit for power monitoring and control, as well as for operational control.


Remote commands and a control stream is received from the MST unit over the AC power distribution lines 101 by the communication module 109 of the Z-SW 400 through the coupler filter module 111 (S7001).


The communication module 109 checks the address to verify that the Z-SW 400 is the intended recipient of the data steam and accepts the command and control instruction stream (S7002).


The communication module 109 of the Z-SW 400 demodulates the received data stream to extract the command and control instructions (S7003).


The communication module 109 further decrypts the command and control instructions to extract the information (S7004).


The extracted information is sent by the communication module 109 to the MCU 109 on the Z-SW 400 via the link connected between a bidirectional communication port on the MCU 109 and the UART on the communication module 111 (S7005).


The MCU 109 receives the information stream and interprets the command and control instructions contained therein. It prepares the operational instructions for transmission to the integrated ZigBee® device 410. (S7006).


The operational instructions are sent to the integrated ZigBee® device 410 of the Z-SW 400 through the bi-directional port 411 and the communication link 412 (S7007).


The operational instructions are sent by the integrated ZigBee® device 410 addressed to the ZigBee® technology enabled connected appliance using pre-established wireless connection (S7008).


The operational instructions sent are received by the addressee ZigBee® enabled device on the connected appliance and provide the necessary inputs to the appliance to change or modify the operational status of the connected appliance (S7009).


The resultant operation status is updated and transmitted back to the integrated ZigBee® device 410 on the Z-SW 400 for transmission back to the originator of the command and control instruction stream through the power line and Internet as necessary (S7010).


Typical Connection for the Units within the Home or Office



FIG. 8 is a block schematic diagram 800 showing powered management and communication connectivity using the four types of units of an exemplary embodiment of the invention. The SW units are used where the requirement is for power connection capability with monitoring and control of power, but without the need to connect a communication device into the PLC LAN.


The Z-SW units allow for power monitoring and control, as well as operational control of the ZigBee® technology enabled appliances. The Z-SW can also be used to connect directly to ZigBee® technology enabled metering devices for monitoring usage, such as gas use and water use.


The ETH devices provide the ability to have a communication device connections to the PLC LAN, while providing a power plug or power source which can be monitored and controlled.


Multiple SW, Z-SW, and ETH units can be used to establish the power monitoring and control for the home appliances and provide connectivity for data communication on the PLC LAN level.


The use of a single MST provides the capability to establish a WAN gateway, thus enabling the PLC LAN to communicate with the outside world in view of various security and connection rules. The MST is also used as a collection and compilation point for power monitoring, where the power usage within the home with connected SW, Z-SW, and ETH units is received and compiled. Because there is connectivity with control capability on each SW, Z-SW, and ETH unit, the power delivery through each of these SW, Z-SW, and ETH units can be monitored and controlled from any of the communication devices connected to the PLC LAN. Further, this collected information on any of the power plugs can be accessed from the WAN using connected communication devices to monitor the status and provide remote control commands through the WAN gateway. This capability is controlled by the permissions, authorizations, and security rules established for connection into the PLC LAN through the MST.


The MST also acts as a collection and compilation point for the operational status of the ZigBee® enabled appliances. This enables the user to have complete information concerning the impact of various operational decisions on the operation and working of the ZigBee® enabled appliances over specific periods for budgeting and control purposes.


Because communication connections to the outside world and within the PLC LAN are all broadband enabled, the system can provide steaming media capability within the PLC LAN. It can also access and enable streaming media delivery to display devices connected using ETH units through the WAN gateway.


To facilitate macro level collection and compilation of power usage information, the collected power monitoring and usage information is transmitted over the WAN gateway to one or more central power usage collection units. These units collect the data for analysis and to provide input to the public bodies for use in making policy decisions on greenhouse gas reduction requirements, etc.


Although the invention is described herein with reference to the preferred embodiment, one skilled in the art will readily appreciate that other applications may be substituted for those set forth herein without departing from the spirit and scope of the present invention. Accordingly, the invention should only be limited by the Claims included below.

Claims
  • 1. A ZigBee®-enabled power switch apparatus (Z-SW) for monitoring and control of power usage of one or more ZigBee® technology enabled appliances, the Z-SW comprising: a power meter;a relay unit; anda ZigBee device that enables the Z-SW with ZigBee® technology for communication with ZigBee® technology enabled appliances;wherein the ZigBee® device is coupled to an AC power distribution line;wherein a ZigBee® technology enabled appliance is coupled to the Z-SW, and the power meter and relay are configured to control a flow of power from the AC power distribution line to the ZigBee® technology enabled appliance;wherein the ZigBee® device is configured to communicate over a wireless network with an associated ZigBee® technology enabled appliance;wherein the Zigbee® device is further configured to: collect operational status information from the ZigBee® technology enabled appliance; andsend operational instructions to the associated ZigBee® technology enabled appliance.
  • 2. The Z-SW of claim 1, further comprising: a micro controller unit (MCU) module connected to the power meter and relay unit, the MCU configured for receiving power usage information and relay status from the power meter and relay unit;the MCU further coupled to the Zigbee® device, the MCU configured to receive operational information from and relay operational instructions to the ZigBee® technology enabled appliance coupled to the Z-SW via the Zigbee® device; andthe Zigbee® device configured to receive the operational instructions from the MCU and to control the operation of the ZigBee® technology enabled appliance coupled to the Z-SW based on the operational instructions received from the MCU.
  • 3. The Z-SW of claim 2, further comprising: a communication module connected to the MCU, the communication module configured to encrypt and modulate information received from the MCU and send the encrypted and modulated information over the AC power distribution line;where the communication module is further configured to decrypt and modulate information received over the AC power distribution line and provide the decrypted and modulated information to the MCU; andwherein the power meter and relay are configured to control a flow of power to the power plug from the AC power distribution lines.
  • 4. A power line communication network comprising: A PLC-based LAN established over AC power distribution lines;a ZigBee®-enabled power switch apparatus (Z-SW) for monitoring and control of power usage of one or more ZigBee® technology enabled appliances, comprising: a power meter;a relay unit; anda ZigBee device that enables the Z-SW with ZigBee® technology for communication with ZigBee® technology enabled appliances;wherein the Zigbee® device is configured to: collect operational status information from the ZigBee® technology enabled appliance; andsend operational instructions to the associated ZigBee® technology enabled appliance; andan intelligent master sensor (MST) configured to: collect, compile, and communicate the operational status information over the PLC-based LAN; andreceive instructions over the PLC-based LAN and deliver the instructions to the ZigBee®-enabled power switch apparatus for effecting control of the ZigBee® technology enabled appliance.
  • 5. The power line communication network of claim 4, further comprising: a communication and power management sensor (ETH);wherein the PLC-based LAN delivers streaming media to and from the ETH.
  • 6. The power line communication network of claim 4, wherein the Z-SW is configured for connecting a ZigBee® technology enabled appliance to the AC power distribution line; and wherein the Z-SW is configured for monitoring power consumption by, and to effect remote control of, a ZigBee® technology enabled appliance connected thereto.
  • 7. The power line communication network of claim 4, wherein one or more Z-SW, MST, or ETH further comprises: a communication module configured for modulating the collected information to a first communication data stream for transmission over the PLC-based (LAN); andthe communications module configured for demodulating a second communication stream that is received over the PLC-based LAN, the second communication data stream providing command and control instructions for power control of a power flow to the associated ZigBee® technology enabled appliance.
  • 8. The power line communication network of claim 7, wherein one or more Z-SW, MST, or ETH further comprises: the communication module configured to transmit and receive over a narrowband communication frequency band to effect narrowband communication over the PLC-based LAN; orthe communication module configured to transmit and receive over a broadband communication frequency band to effect broadband communication over the PLC-based LAN.
  • 9. The power line communication network of claim 4, wherein the ETH is configured for connecting a ZigBee® technology enabled appliance to the AC power distribution line; wherein the ETH is configured for monitoring power consumption by, and to effect remote control of, a ZigBee® technology enabled appliance connected thereto;wherein the ETH is configured for providing broadband communication over the PLC-based LAN.
  • 10. The power line communication network of claim 4, wherein the Z-SW further comprises a coupler filter module connected to the communication module and the AC power distribution line.
  • 11. A method for monitoring and control of power usage of one or more ZigBee® technology enabled appliances, comprising: providing a Zigbee®-enabled power switch (Z-SW) apparatus comprising: a power meter;a relay unit; anda ZigBee device that enables the Z-SW with ZigBee® technology for communication with ZigBee® technology enabled appliances;wherein the ZigBee® device is coupled to an AC power distribution line;coupling an intelligent master sensor (MST) to the AC power distribution line;the MST receiving instructions;the MST delivering the instructions to the Z-SW over a PLC-based LAN; andresponsive to receiving the instructions from the MST, the Z-SW delivering operational instructions to an associated Zigbee® technology enabled appliance over a wireless network;wherein the operational instructions control the operation of the associated Zigbee® technology enabled appliance.
  • 12. The method of claim 11, wherein the MST receives instructions that are sent over a broadband network outside of the PLC-based LAN through a router connected to the MST.
  • 13. The method of claim 11, further comprising: a Zigbee® technology enabled appliance sending operational status information over a wireless network to an associated Z-SW;the associated Z-SW collecting operational status information from the ZigBee® technology enabled appliance;the associated Z-SW sending the operational status over the PLC-based LAN to the MST;the MST collecting and compiling operational status information;the MST communicating compiled operational status over a broadband network outside of the PLC-based LAN through a network router connected to the MST.
  • 14. The method of claim 11, further comprising: the Z-SW connecting a ZigBee® technology enabled appliance to the AC power distribution line; andthe Z-SW monitoring power consumption by the ZigBee® technology enabled appliance connected thereto.
CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 13/197,623, filed Aug. 3, 2011, which in turn is a continuation-in-part of U.S. patent application Ser. No. 13/153,194, filed Jun. 3, 2011, which in turn claims priority from U.S. patent application Ser. No. 13/032,454, filed Feb. 22, 2011, each of which is incorporated herein in its entirety by this reference thereto.

Continuations (1)
Number Date Country
Parent 13197623 Aug 2011 US
Child 14167858 US
Continuation in Parts (1)
Number Date Country
Parent 13153194 Jun 2011 US
Child 13197623 US