DE10048348C2 - Procedure for system synchronization of PLC systems - Google Patents

Description

The invention relates to a method for system synchronization tion of PLC systems according to the preamble of claim 1.

The high bit rate data communication via the electricity supplier power lines of electrical devices, the so-called Powerline Communication (PLC) depends on the channel qualities in the frequency range provided for the channels chen, these are for a so-called access area of Fre frequency range from 2.2 MHz to 9.4 MHz and for a so-called ten in-house range the frequency range from 10.5 MHz to 24 MHz, sometimes very difficult or even impossible. Some the reasons for this are frequency selective coupling impedances, Line loss and radio interference on the lines act.

Due to the typical lengths of the cabling of a Ge building forms the wiring of the building in a good proximity an antenna array that picks up signals from outside and can radiate to the outside. According to existing EMC regulations writings, d. H. Electromagnetic Compatibility Regulations emissivity (EMC), the radiation power may be a predetermined one Do not exceed dimension. The aspirations are going today the radiation output of cabling is as low as possible hold.

One of the measures to minimize the radiation power the Powerline Communication is the signals from PLC devices symmetrical with a mutual phase shift of 180 degrees on the individual power supply lines system, that is to say on the phase leading power line and the return line. In this case arises a common mode current between the affected power lines zero size. A common mode stream with a size of unequal  zero leads to an undesirable, correspondingly large Radiation from the power line system. Although a network line system should never be completely radiation-free, because with increasing distance from the PLC devices a phase ver never completely shift the signals between the power lines can be excluded with the method of symmetrical Coupling the PLC signals, however, this effect is minimal held. In any case, the EMC technical requirements can be respected.

The symmetrical coupling of the PLC signals from PLC devices into the power grid causes the power supplier provides attenuation for these signals, through which the radiation power of the power supply network in With respect to these signals is reduced. The damping has, however also the disadvantage that in some cases it is so big that there are PLC devices connected to the power supply system can no longer initialize each other because their Si gnale no longer reach the other PLC devices. This Problem is generally under the term "hidden knot" (hidden node) known.

The starting phase of communication between communications willing PLC devices is the most critical phase during the whole communication. The PLC devices can already be recognized here not each other, there is a communication link between from the start of the PLC devices. The Com Communication failed from the start. On the On the other hand, it is the case that when the PLC devices on the An catch at least recognize each other, they can go on check the quality of your communication channel and in Ab depending on the result of this review according to ro bust transmission method for further communication use. The communication process is not from then on start failing, but there is still a successful one Communication.  

DE 197 04 018 A1 describes a method for system synchronization nization of PLC systems in which the PLC Initialize devices to the extent that the following a data exchange between the relevant PLC devices is feasible. Here, the communication signals in the power line via a HF Grid coupling coupled in.

From DE 43 28 523 A1 a device for Coupling of PLC signals known, in which the PLC signals depending on the transmission quality of the power line of the power supply system from a current transmission channel is converted to a second transmission channel. The communication between the PLC systems takes place here exclusively in asymmetrical transmission.

The object of the present invention is therefore a method ren of the type mentioned at the outset that a high Er Identity security in the start phase of PLC connections guaranteed.

This object is achieved according to the invention by a method solves that indicated in the characterizing part of claim 1 benen procedural steps.

After that, at least in the start phase of a PLC connection development or in the corresponding synchronization phase the PLC signals from PLC devices are not symmetrical but rather coupled in an asymmetrical manner, thereby damping losses for signal transmission by, for example, ver reduce different phases within a building. later than at least after the synchronization of the PLC system PLCs involved in the PLC system to be synchronized Devices set a symmetrical transmission mode. Due to the asymmetrical coupling of the PLC signals for a conscious radiation of the PLC signals from the network cables of the associated power supply system. The PLC signals  are partly at a first point in the network line system in the air and a second Put it back into the power line system from the air coupled. This means that the PLC signals are not in this phase transmitted only through the lines, but also partly over the air. For two communication devices, this means that reduces the impedance of their signal transmission path is. This gives stronger signals to the Ge in question advise. The probability of recognition is thereby increased. Once PLC devices have recognized each other, they can agree on another suitable type of signal transmission, which, for example, on a symmetrical coupling into the System based and otherwise robust against difficult Si gnalübertragungsverbindungen. Know each other PLC devices, they can switch to a defined state. The PLC devices recognize each other despite the asymmetrical on coupling of your PLC signals, you can also in egg switch a defined state. The addressed PLC device is then not available and a connection is essential not possible. Pending work can then be carried out by the PLC devices can be resumed as soon as possible.

Although it is in the starting phase of a communication between relevant PLC devices due to this procedure that EMC-technically defined radiation values exceed be paced. This fact can be accepted because this crossing occurs only once at the beginning of a verb development and then occurs only briefly. The before part but is that a decision about it much faster can be made whether a desired partner device before is or not or that a desired partner device can be initialized, otherwise due to un cheaper damping factors would no longer have been recognized.

These advantages are achieved by being conscious of the egg property of cabling, for example, of buildings tennen array and thus the air next to a desired one  Powerline route as a transmission path for a short Time period is used to recognize communication ensure partners.

Advantageous embodiments of the invention are the subject of subclaims.

Then on the one hand a maximum possible Ab radiation and on the other hand time duration of this maximum possible radiation is as short as possible hold.

An exemplary embodiment of the invention is described below a drawing explained in more detail. In it show:

Fig. 1 is a schematic representation of a prior art constructed PLC system in which the PLC devices having a symmetrical signal Übertra supply work,

Fig. 2 is a first schematic representation of a PLC system according to the invention, in which the PLC devices work with an asymmetrical signal transmission, and

Fig. 3 shows a second schematic representation of a PLC system according to the inven tion, in which the PLC devices work with an asymmetrical signal transmission.

The PLC system shown schematically in FIG. 1 has a PLC device generally shown as a generator G, a transmission link US and a second PLC device generally shown as a receiver E. In Fig. 1, the transmission link US only includes the absolutely necessary power lines of a power supply network belonging to the PLC devices, namely a phase-leading power line and a return line. The current connection of the said power lines is not shown in FIG. 1 Darge. The figure shows the basic signaling interface with which, according to FIG. 1, the first PLC device couples the PLC signals onto the power lines and with which the second PLC device couples out the PLC signals coupled in from the first PLC device ,

The coupling of the PLC signals generated by the first PLC device takes place technically in a symmetrical manner, that is, the PLC signals are simultaneously coupled to the two power lines in FIG. 1 with the proviso that the PLC signals on the one power line can be coupled in phase shifted by 180 degrees compared to the PLC signals on the other power line.

This issue is shown in Fig. 1 with the two transmission characteristics ÜK1 and ÜK2 schematically Darge. In this case, the electromagnetic effects of the signals on the two lines cancel each other out and, ideally, a zero-size common mode current is produced. If there is no common mode current, there is no signal radiation on the lines. The signals are transmitted purely on the lines. The line system has an attenuation for signal transmission, which also determines whether a PLC device located further away from a sending PLC device can still recognize the PLC signals sent by the sending device. The greater this impedance, the more likely it is that the receiving PLC device will no longer recognize these signals.

In FIGS. 2 and 3 similar PLC systems are each shows ge. In FIGS. 2 and 3, the respective Übertra are not transmission link has more particularly been found. For this, a respective so-called coupling unit is shown, by means of which the first PLC devices, now designated in each case with the PLC unit, are connected to the respective associated line system for power supply and signal transmission. The coupling units galvanically separate the respective PLC devices from the respective power line system, which is shown in FIGS. 2 and 3 with the conductors P for the phase leading power line, N for the returning power line and PE for the protective line.

The special feature of the arrangements according to FIGS. 2 and 3 is the fact that the respective PLC devices or PLC units are coupled to a control CTRL. With the help of the CTRL control, the respective PLC devices are able to connect one of their power lines to a constant, selected reference potential at specified times. In FIGS. 2 and 3 of this reference potential is realized by way of example to the ground point or ground wire.

According to FIG. 2, the control STRG acts after the coupling unit, while according to FIG. 3 it acts before the coupling unit. The only decisive factor is that a network conductor of the power supply system and thus of the signal transmission system controlled by the relevant PLC device is excluded from the signal transmission to a predetermined extent. Depending on the extent to which the relevant power line is excluded from the signal transmission, a common-mode current occurs between the power lines, which can rise to a maximum. The common mode current receives a maximum if no PLC signal is transmitted on one power line and the most powerful PLC signal is transmitted on the other power line. In comparison to symmetrical signal transmission, this type of signal transmission can be viewed as asymmetrical signal transmission.

Depending on the size of the common-mode current, the mains cable works system as an antenna array and emits the PLC signals. At the same time, the network management system also provides an emp catcher, so that the radiated PLC signals on again be coupled. This means for a receiver PLC device ultimately that the impedance for signal transmission redu is adorned because the PLC signals at least in a sub-area  of the total distance to be transmitted by air represents a transmission path with low impedance.

This fact make use of the arrangements according to the Fig. 2 and 3 thereto from, at least in the initialization phase a Si gnalübertragung the impedance for the signal transmission to minimize to thereby otherwise difficult to reach receiver to initialize devices. Once the devices in question have recognized each other, you can switch back to the symmetrical signal transmission method in order to minimize unwanted radiation from the power lines. The further signal transmission can take place with robust transmission methods, to which the PLC devices may have agreed in the initialization phase.

Claims (2)

1. A method for system synchronization of PLC systems in such a way that the PLC devices belonging to a PLC system to be synchronized mutually initialize each other to such an extent that data exchange between the relevant PLC devices can subsequently be carried out, characterized in that that in order to carry out at least the start phase of the synchronization of the PLC devices involved in a PLC system to be synchronized, a transmission mode is switched on in which PLC signals are generated in an asymmetrical manner on the power lines of the associated power supply system and at the latest after Implementation of the synchronization of the PLC system is set by the PLC devices involved in the PLC system to be synchronized, a symmetrical transmission mode. 2. The method according to claim 1, characterized in net that the asymmetrical generation of PLC signals in the way that is carried out between the network of the power supply system a maximum common mode Current.