DE10121048A1 - Arrangement for propagating information via mains has data transmitter with transmission protocol comparator and error assessor connected to mains via transformer/modulator - Google Patents

Abstract

The arrangement has a data transmitter with a data generator, decoder and scheduler. The data transmitter is connected to the mains via a transformer/modulator. A supply stage has a voltage supply and a transformer /demodulator and passes incident data to a data receiver with a decoder, assessor, evaluator, intermediate memory and identification memory. The transmitter has a transmission protocol comparator and a transmission error assessor. The arrangement has a data transmitter (A) with a data generator, decoder and scheduler. The data transmitter is connected to the mains (C) via a transformer/modulator (B). A supply stage (D) has a voltage supply and a transformer /demodulator (D2) and passes incident data to a data receiver (E) with a decoder, assessor, evaluator, intermediate memory and identification memory. The data transmitter contains a transmission protocol comparator and a transmission error assessor for checking the data transmission. AN Independent claim is also included for the following: a method of propagating information via the mains.

Description

The invention relates to an arrangement and a method for distribution of information about the power grid, especially for devices that are not must be constantly connected to the mains, in particular Cell phones, home appliances, game consoles, radio and television sets count with or without a channel for data reception. This procedure fin det especially in advertising or software update application.

In addition to the dissemination of information via radio or communication networks, where separate connections are used for data transmission as is well known, power supply lines for the dissemination of Information. The Po uses such methods of information transmission werline communication, especially for information transfer from with the Internet connected devices.

A disadvantage of this method is that devices without special communication tion interface, especially household appliances, game consoles and gameboys are supplied with data or, in the case of devices with a communication interface, in particular special cell phones, radio and television sets, the amount of data transfer very is limited.

Data with non-critical requirements for transmission security and transmission speed are usually treated just like all other data and  burden the reception performance of the connected devices. The device characteristics The device or address in a network is usually fixed and used in the devices set independently of the application, so that no logical connection with the others Criteria such as B. Device type and device manufacturer is possible.

Based on the dissemination of information about the power grid to devices with a fixed device identifier, the invention has for its object a Arrangement and method for disseminating information over the power grid to realize, especially for devices that are not constantly connected to the power grid must be closed and with or without a channel for data reception are allowed, as well as the optimization of the network operation by usage ore addressing of the recipients.

This task is accomplished through an arrangement to disseminate information about the power grid with the features specified in claim 1, and by a Method with the features specified in claim 4 solved. Favorable off designs are specified in further claims.

The data feed is preferably cyclical at the low voltage side of the power grid using special data protocols, which are made up of one Data utilization code, a data recipient identification and the user data together mensetzen. Devices that have a connection to the power grid now use the Possibility of data transmission and are supplied with additional data, especially portable devices that are charged or operated using a power supply. Another advantage is the possibility of optimizing network operations through application-oriented addressing of the data recipient. The Data assigned to the devices with the appropriate identifier, transferred and opened plays. There is also the possibility that the data receiver a new Ken receive the address or address to assign a new data utilization to them. Through a data scheduler that defines the transmission cycles for the data packets the possibility of data collisions avoided.

A further description of the invention is based on exemplary embodiments, which are shown in the following drawing figures.  

Show it:

Fig. 1 shows a schematic representation of the data transmission,

Fig. 2, the composition of the transmission protocol, and

Fig. 3.1, 3.2, 3.3 the process steps.

Fig. 1 shows an arrangement according to the invention for the transmission of information via a power network C to permanently or only temporarily connected electrical devices G via a power supply unit D. In a data transmitter A, which contains a data provider A1, a data encoder A2 and a data scheduler A3 , the information to be transmitted is made available to the power network C by means of a transmitter / modulator B. For this purpose, the data to be transmitted are packed in the data encoder A2 in a transmission protocol readable by a data receiver E, which is explained in more detail with reference to FIG. 2.

The data scheduler A3 specifies the transmission cycles for the individual data packets be sent at specified times. The data transmitter A transmits the information to be transmitted to the power network C via the transmit / mod lator B, the z. B. is arranged in a transformer station. The transmit / modulator B on the one hand represents the electrical isolation between the information and power network and on the other hand brings the electronic data signals into the power network C, wel ches is able to transmit the encoded data. The power supply D, the one Includes power supply D1 and a transmit demodulator D2 set up to transmit the incoming data to the data receiver E, the data receiver E being a data decoder E1, a data evaluator E2, a data processing part E3, a buffer E4 and an identification file contains E5.

After demodulation in the transmission demodulator D2 and decoding in the decoder E1 using a receiver identifier P3, which is shown in more detail in FIG. 2, the data receiver E checks whether the information is intended for a particular device or a specific device group and decides whether it should use the data sent depending on the test result.

A changeable device is located in the identification memory E5 of the data receiver E. identifier that determines whether the data sent is intended for the device and causes the data to be received if the result is positive. In the data evaluator E2 is a check of the data after its determination in order to send it to the concerned Data processing part E3, to the identification memory E5 or to the intermediate to forward the memory E4. If the data includes a new device identifier ten, the device identifier of the data receiver E. changes

For checking and documenting data transfer via the Power network C, a monitoring device G1 can be arranged, which are the same Components such as the device G, and the data utilization code P2, the data receiver identifier P3 and the user data P4 the transmission protocol comparator A4 of data transmitter A sends back, which then evaluates the data tet. If errors are found in the transmission protocol comparator A4 transmitted a message to the transmission error evaluator A5 for error analysis. The monitoring device G1 can via the power supply or another informat on channel with data transmitter A deliver this feedback.

Fig. 2 shows the composition of the transmission protocol for the optimization of the network operation by application-oriented addressing of the data receiver. The data to be transmitted are coded with a transmission protocol identifier P1, which depends on the protocols occurring in the network. This data packet is further composed of a data utilization code P2, a data receiver identifier P3, the user data P4 and a protocol termination P5. The data utilization code P2 carries the information as to whether the data receiver identification P3 is to be compared and defines the intended use of the data. The possible uses of the data must be defined once, e.g. B. the presentation of the data on a display. The data is then used on the individual devices or device groups depending on the intended use.

Depending on the network size, the length of the data recipients is determined P3. The maximum length of the possible user data P4 is determined by the permissible determined for each protocol. Depending on the structure of the used  Protocols P5 are added to protocols in the network. Should the Da Data receiver identification P3 cannot be compared, the data receiver takes over E the user data P4, if the selected type of data utilization is intended for it, d. H. z. B. all televisions in a network take over the data for advertising without they must have a defined address in the network.

Figs. 3.1, 3.2, and 3.3 show the schematic process sequence using the example of the provision of advertising data to a data receiver E, wherein the method is in several individual steps 1 to 16, and some to be traversed procedural renszweige divided ad.

In a first prepared step 1 of FIG. 3.1, the advertisement in the data provider A1 is converted into transferable data and made available on a server. After coding the data in step 2 in the data encoder A2 by specifying the transmission protocol identifier P1 and entering the data usage code P2 for advertising, and the identifier as to whether the data receiver identifier P3 is to be compared, the data receiver identifier P3, the user data P4 for the representation of the Advertising and protocol completion P5 added. The data scheduler A3 then determines in step 3 the time of transmission in accordance with the ordered times of the provider of the advertising data. If the transmission time is reached in the following step 4 (query result yes), in step S the data is fed in via the transformer / modulator B into the network. If the time for sending the data has not been reached, a waiting loop is set up until the released sending time. After the transmission of data over the electricity network C, the data in the transmitter / demodulator D2 of the power supply D in step 6 are coupled and then to the data receiver E in method step 7 a übertra gene. If it is in the data receiver to a monitoring device G1, who to the Data in method step 7 b forwarded to the transmission protocol comparator A4.

In step 8 , the transmission protocol identifier P1 is evaluated in the data evaluator E2. If the protocol identifier P1 is not present, the system waits until a transmission protocol identifier P1 is recognized and, in connection step 9, the data utilization code P2 is decrypted and the method continues to step 10 or to process branch d.

In step 10 it is checked whether the data receiver identifier P3 should be compared. If the test of the comparison of the data receiver identification P3 does not lead to a positive result, the data receiver identification comparison is skipped (method branch c). When determining the correspondence of the sent data receiver identifier P3 with the identifier of the device G in step 11 (method branch a), which can be seen in FIG. 3.2, the data utilization code P2 is evaluated for the representation of the sent data in method step 12 , If this is not the case, the incoming data are not used by the receiver E for the display.

The use of the data in accordance with its determination is determined in subroutines in step 13 . In step 14 , the decision about the destination of the data is made. If the data for the data processing part E3 display be determined, they are sent to the display in step 15 b and step 16 in the last method is shown as advertising on the display. If the data cannot be displayed immediately, the data are stored as shown in step 15 a, in the buffer E4 of the device G and, after the display has been released, are transferred to it.

To check the data transmission and document a data transmission over the power network C, the data utilization code P2 received by the monitoring device G1, the data receiver identification P3 and the user data P4 are compared and compared according to method steps 20-25 , which are shown in FIG. 3.3 As shown in step 7 b, the transmission protocol comparator A4 is sent via the method branch b of the data transmitter A.

In steps 20 , 21 , 22 , 23 it can be seen that, with the correct protocol identifier P1, correct data utilization code P2 and agreement of the receiver identifier P3, the data transmitter A detects that the user data P4 were available in the power network C without errors. In order to determine errors in the data transmission in the communication protocol comparator A4 is made at step 24 a a message to the DA tenscheduler A3, whereupon this such a shown classifies the data packet in step 25 for again sending and re-transmits the data. At the same time, in step b 24 a message to a Übertragungsfehlerbewertar A5 transmitted for error analysis and to initiate the corresponding actions, which b in the step 25 is set is.

Claims (5)

1. Arrangement for the transmission of information via a power network (C) to it permanently or only temporarily connected electrical devices (G) via a power supply unit (D), where

• a) a data transmitter (A) is present which contains a data provider (A1), a data encoder (A2), a data scheduler (A3),
• b) the data transmitter (A) is connected to the power network (C) by means of a transmitter / modulator (B),
• c) the power supply unit (D) contains a voltage supply (D1) and a transmitter / demodulator (D2) and is set up to transmit the incoming data to a data receiver (E), and the data receiver (E) has a data end encoder (E1 ), a data evaluator (E2), a data processing part (E3), a buffer (E4) and an identification memory ( 25 ), and wherein
• d) the data transmitter (A) contains a transmission protocol comparator (A4) and a transmission error evaluator (A5) for checking the data transmission.

2. Arrangement according to claim 1, characterized in that in the Kennspei a changeable device address is stored (E5) of the data receiver (E), which after a comparison in the data evaluator (E2) and if they match with the code valid for the device address change by means of the received Data is updated. 3. Arrangement according to claim 1 and 2, characterized in that the output of the data takes place via the data processing part (E3), which in particular is a Ad is. 4. A method for transmitting information via a power network (C) to electrical devices (G) connected to it permanently or only temporarily, whereby

• a) the data to be transmitted in a data transmitter (A) with a transmission protocol identifier (P1), a data utilization code (P2), a data receiver identifier (P3), the user data (P4) and a protocol completion (P5) put together, coded and supplemented .
• b) at defined transmission times, preferably cyclically, the data packets are sent, the data packets being fed into the power network (C) with the aid of a transmitter / modulator (B),
• c) at the receiving end after demodulation and decoding, using the receiver identifier (P3), it is checked whether the information is intended for the respective device or a specific group of devices and whether this is used depending on the test result, the type of use being determined by the data recovery code (P2) dependent, and
• d) in a data evaluator (E2) the data utilization code (P2) of the data is checked after its determination and this data is sent to a relevant data utilization part (E3) or to a buffer (E4) or if the data is used for re-addressing to an identifier memory (E5) be forwarded.

5. The method according to claim 4, characterized in that for checking the data transmission via the power network (C) a monitoring device (G1) exists, which contains a power supply unit (D) and a data receiver (E), the protocol identifier (P1) , the data utilization code (P2), the data receiver identification (P3) and the user data (P4) a transmission protocol comparator (A4) of the data transmitter (A) and

• a) with correct protocol identifier (P1), correct data utilization code (P2) and agreement of the recipient identifier (P3) of the data transmitter (A) recognizes that the user data (P4) were available on the power network (C) without errors, or
• b) when errors in the transmission protocol comparator (A4) are detected, a message is sent to a data scheduler (A3) that this arranges the data packet for retransmission, the data is retransmitted and at the same time a message to a transmission error evaluator (A5) for error analysis transmitted.