Method of isolating data in a power line communications network

Isolating data in a power line communications system. Although plural subscribers receive electric power distributed from a common distribution transformer, it is desirable to isolate their branch lines from one another when those branch lines are used to conduct data communications as a supplement to electric power delivery. This isolation of branch lines implemented in a centralized way at the distribution transformer, or alternatively, in a distributed way at each subscriber's premises. These implementations are made using low pass filters (which pass the power but block the data) and power line communications routers or power line communications repeaters.

INTRODUCTION

The present invention relates generally to the field of electrical communications via power lines. More particularly, the present invention relates to isolating data in a power line communications system.

BACKGROUND OF THE INVENTION

A typical electric distribution configuration has a transformer which steps medium voltage down to a few hundred volts AC (typically between 100 and 240 VAC). The Low Voltage (LV) is fed to several homes.

Referring toFIG. 1, the typical electric power distribution architecture is illustrated. No filter or other barrier is employed to isolate data from one residence to the next. Using this architecture for a power line communications system, typically a power line signal containing the data will be fed at the transformer. There are four potential problems with this topology for communications.

First, the bandwidth is shared between plural subscribers. Second, noise from another subscriber using a different type of power line communication system or noise from another subscriber's appliances may cause interference. Third, subscribers using the same system can interact with each other. Fourth, since one subscriber receives the other subscriber's data, there is a lack of security.

Thus, what is needed is a way of isolating data from subscriber to subscriber to alleviate the problems discussed above.

SUMMARY OF THE INVENTION

It is an object of the present invention to enable isolation of data from subscriber to subscriber.

It is another object of the present invention to enable isolation of data from a subscriber to the distribution transformer.

Isolation structures to realize these objects are implemented in a centralized way at the distribution transformer, or alternatively, in a distributed way at each subscriber's premises. These implementations are made using low pass filters (which pass the power but block the data) and power line communications routers or power line communications repeaters.

DETAILED DESCRIPTION OF THE INVENTION

According to alternate embodiments, data isolation is accomplished in a centralized manner, in a distributed manner (i.e., at the subscriber), or in a hybrid manner that is a combination of centralized and distributed.

According to one aspect of the invention, a system provides for network communications isolation in a branch line connecting a subscriber device at a subscriber premises to a network. The system includes an electric power distribution transformer, a branch line (connected between the transformer and the subscriber's premises), a low pass filter, and a power line communications router. The low pass filter connected in the branch line at a location adjacent the transformer. The power line communications router is connected to the network and coupled to the branch line at a location adjacent the filter, on the subscriber side of the filter. When the subscriber device is coupled to the branch line, the subscriber device is coupled to the network and is isolated from the transformer by the filter.

According to another aspect of the invention a network coupler. The network coupler provides network communications isolation in a branch line connected to a subscriber premises through an electric power meter. The network coupler includes a low pass filter and a power line communications repeater. The low pass filter is coupled to the branch line adjacent to the power meter. The power line communications repeater is connected to the branch line across the low pass filter.

On the one hand, the power line communications repeater is connected across both the low pass filter and the power meter. In the alternative, the power line communications repeater is connected across only the low pass filter. The low pass filter is disposed either on the subscriber side of the power meter, or on the transformer side of the power meter.

According to yet another aspect of the present invention, a network isolator provides network communications isolation in a branch line connected to a subscriber premises through an electric power meter. The isolation is provided between a network located at the subscriber premises a transformer connected to the branch line. The network isolator includes a low pass filter. The low pass filter is coupled to the branch line adjacent to the power meter. The low pass filter is disposed either on the subscriber side of the power meter, or on the transformer side of the power meter.

Referring toFIG. 2, a centralized power line communications (PLC) router210is illustrated. The centralized PLC router210is connected separately to each branch line, which in turn connects to the subscriber. A filter220passes the high power electricity (100 VAC to 240 VAC) but blocks the power line communications signal. This filter220is implemented using electronic components such as inductors, capacitors and resistors. This method requires splicing the electric power line and inserting the filter210in series with the line230.

A less expensive way of implementing this filter, which does not require cutting the power line, uses a ferrite toroid as a common-mode choke. This is done by simply feeding an electric power line through a toroid, thus allowing the electric power (50-60 Hz) to pass yet blocking the higher frequency signals that contain the power line communications data. In most situations the toroid method is preferred.

In conjunction with the centralized method, or as an alternative, data is isolated using a distributed approach. In this approach a filter (such as described above) is placed at the subscriber's location. A power line data repeater, which regenerates the data, is connected in parallel with the filtering device. This topology addresses the noise, interference and security issues. However, the bandwidth is shared between each subscriber connected to the transformer.

Referring toFIG. 3a block diagram view of an embodiment of the present invention having isolation before the power meter300is illustrated. This is an implementation according to a distributed topology. A PLC repeater310and a filter320are connected in parallel with one another and in series with the power meter300. The power meter300is disposed between the subscriber's house340and the PLC repeater310.

Referring toFIG. 4a block diagram view of an embodiment of the present invention having isolation after the power meter400is illustrated. This is another implementation according to a distributed topology. A PLC repeater410and a filter420are connected in parallel with one another and in series with the power meter400. The PLC repeater410is disposed between the subscriber's house440and the power meter400.

Functionally, the differences between the distributed topology implementations illustrated inFIGS. 3 & 4are insubstantial. However, depending on the deployment one may be easier to implement than the other.

Referring toFIG. 5, a block diagram view of an embodiment of the present invention having isolation bridging the power meter is illustrated. A filter520is connected in series with the power meter500, and that series combination is connected in parallel with a PLC repeater510.

Although the distributed topology of this embodiment is potentially difficult to deploy, it has certain performance advantages. Performance according to this embodiment is superior since the electric meter500presents some attenuation of the power line communication signals. Thus, in this topology the PLC repeater510repeats signals across the filter520and electric meter500. This achieves a better signal-to-noise ratio by avoiding the attenuation that would otherwise be introduced by the electric meter500.

Referring toFIGS. 6 & 7, a filtering device is placed on the power line adjacent the subscriber's premises. This is useful in cases where an internal Local Area Network (LAN) exists within the premises and access to a Wide Area Network (WAN) in not required. This provides security for the LAN as well as reduces interference from the outside. It also isolates the LAN from the WAN in case a WAN is deployed. According to the embodiment illustrated inFIG. 6, the filter610and the electric meter620are connected in a serial with one another, with the filter610before the electric meter620. Alternatively,FIG. 7illustrates the filter710and the electric meter720as being connected in a serial with one another, with the filter710placed after the electric meter720. The arrangement according to both of these illustrated topologies functionally perform the same. However, depending on the deployment one may be easier to implement than the other.

The present invention has been described in terms of preferred embodiments, however, it will be appreciated that various modifications and improvements may be made without departing from the scope of the invention.