DE10353498A1 - Allocating subchannels within frequency transmission band for data transmission, arranging subchannels so that their frequency bandwidths do not overlap - Google Patents

Abstract

A number of subchannels are determined within a frequency transmission band each subchannel having a set frequency bandwidth. The subchannels are arranged regarding their frequency position so that the frequency bandwidths of respective subchannels do not overlap. A minimal frequency bandwidth is maintained between frequency boundaries of respective neighboring subchannels so that only a minimal required frequency bandwidth of the frequency transmission band is occupied. An independent claim is also included for the application of the subchannel allocation method to the data transmission over the cable line.

Description

The The invention relates to a method for assigning subchannels within a frequency transmission band and the use of such a method, in particular for the transmission of Data about a high voltage line.

to Coordination of data streams over a wide variety of data channels Frequency bands are often used according to national guidelines Data transfer types from the national authorities provided. For better utilization of these predetermined frequency transmission bands especially for the data and voice transmission the data is not over the entire available Frequency transmission bandwidth but in subfrequency bands of the frequency transmission band - also called subchannels - for better capacity utilization coordinated transfer.

conventional Procedure for the transmission of Data in subchannels are characterized in that in the frequency transmission band, the positions the subchannels within the frequency transmission band given and for the transfer fixed are fixed. This fixed allocation of the sub-channel frequency bands will for one clear reconstruction of the transmitted Data selected, because thereby by the receiver the information about the number of subchannels does not have to be determined. The sequence and the frequency band distances of the subchannels within the frequency transmission band are thus also fixed and implemented in the sender and receiver.

That's how it describes DE 43 27 588 A1 a method for transmitting or demodulating a digital signal and a demodulator for decoding that signal. Here, the physical subchannels used due to a terrestrial transmission of digital HDTV signals are fixed and defined in terms of their position and frequency width in the frequency transmission band.

task The present invention is the predetermined frequency band a transmission channel optimal, especially with disturbing transmission influences such as e.g. on power lines, to use.

For this is inventively provided that determines the number and frequency bandwidth of the subchannels to be used and subsequently the subchannels within the frequency transmission band in terms of their frequency position be positioned so that the frequency bandwidths the respective subchannels do not overlap.

in this connection On the one hand, the sequence of the respective subchannels on the frequency transmission band and on the other hand, the respective position of the subchannel within the Frequency transmission bands for the Selection of the positions of the respective subchannels for optimal allocation subchannels - under Observance of the restriction, that no overlaps the subchannels may occur - used become.

Farther is advantageous that the method according to the invention, the positioning the subchannels within the frequency transmission band is provided so that a predetermined minimum frequency band gap maintained between the subchannels becomes. Independently Whether digital or analog data is available, this is one minimum signal to noise ratio between the individual subchannels adhered to and made possible thus a reduced-error transmission the data within the individual subchannels, as this disturbing interference between the individual subchannels be minimized. Another advantage is that the subchannels almost are arranged directly next to each other and thus only an actually required frequency bandwidth of the frequency transmission band is occupied. Considering the minimum frequency band spacing between each subchannel hereby ensures optimum utilization of the frequency bandwidth of the frequency transmission band become. In particular, with still sufficient frequency bandwidth an additional subchannel be added to the existing ones within the frequency band. The determination of the minimum frequency band gap is either to the operator himself or leave is determined by an analysis of the data to be transmitted over the individual subchannels certainly.

It is furthermore advantageous that, in the case of digital data transmission within the subchannels, the digital subchannels are positioned relative to one another such that a maximum frequency band spacing between the individual subchannels is maintained. This is particularly useful in transmission via OFDM (Orthogonal Frequency Division Multiplexing) to achieve better transmission results that improve with greater signal to noise ratio between the subchannels. The selection of a minimum or a maximum frequency band spacing between the subchannels is therefore a question of balancing between the transmission reliability of the data in the individual subchannels (maximum frequency band gaps) and the optimal and effective utilization of the provided frequency transmission band by a plurality of subchannels (minimum frequency band gap).

For the determination the frequency band spacing between the frequency edges of the adjacent ones subchannels becomes an equidistant Frequency bandwidth calculated. This is the sum of the frequency bandwidths formed the individual subchannels and then from the available standing frequency transmission bandwidth subtracted from the system. This value is to be averaged over the number of subchannels and to maintain the calculated frequency band gap between all subchannels. Alternatively, with a simultaneous use of digital and analog data over different subchannels to the frequency edges the respectively adjacent subchannels a maximum and to the frequency edges of each adjacent subchannels with analog data transmission to maintain a minimum frequency band gap. The maximum and minimum frequency band gaps are in turn given by the operator or by a Analysis of the transferred Data about the individual subchannels certainly. In a possible Configuration is the minimum frequency band spacing given to the system. The maximum frequency band gap is over the difference of the total Frequency bandwidth of the frequency transmission band and the still free frequency transmission band over the needed Number of subchannels with maximum frequency band intervals averaged. Alternative optimization methods for the determination of suitable minimum and maximum frequency band intervals also usable in the context of the method according to the invention.

Advantageous is the use of the method according to the invention for data transmission by means Data pumps over Lines, in particular high-voltage lines. Especially for data transmission via high voltage power lines with big Distances and highest different data formats is a flexible use of the predetermined frequency transmission band advantageous.

Further advantageous measures are in the rest dependent claims described; The invention is based on embodiments and the following Figures closer described and it shows:

1 inventive reduction of the frequency band intervals between the individual subchannels;

2 inventive increase in the noise margins in digitally transmitted subchannels.

In the 1 In particular, a minimized frequency band spacing between the individual subchannels is selected for analog data transmission via the subchannels. The frequency transmission band is schematically indicated by the horizontal line. The edge points represent the minimum or maximum frequency of the frequency transmission band to be used, in the high frequency range, for example, 100 kHz and 108 kHz. By optimizing the utilization of the frequency transmission band, it is possible in some cases to add another subchannel (additional subchannel) to the transmission band , The still assignable range of the frequency transmission band must then correspond at least to the frequency bandwidth of the additional subchannel and to a minimum mutual noise margin around the additional subchannel.

In the 2 For transmission of data via the subchannels, a maximum frequency band spacing between the individual subchannels is selected. As a result, the transmission quality of digital data is improved, in particular in the case of different multiplexing methods. With a large frequency band spacing between the individual subchannels, the signal-to-noise ratio is significantly improved in digital data transmission in particular.

Claims (8)

Method for assigning subchannels within a frequency transmission band, characterized in that determines the number and the respective frequency bandwidth of the subchannels and then the subchannels are assigned due to the so made determination within the frequency transmission band with respect to their frequency position so that the frequency bandwidths of the respective subchannels do not overlap , Method according to claim 1, characterized in that that the subchannels within the frequency transmission band be assigned so that a minimum frequency band gap between the frequency edges the respective adjacent subchannels complied and thus only a minimal needed Frequency bandwidth of the frequency transmission band is occupied. Method according to claim 1, characterized in that that the subchannels within the frequency transmission band be assigned so that a maximum frequency band spacing between the frequency edges the respective adjacent subchannels, in particular for transmission of digital data, and thus the entire frequency bandwidth occupied by the frequency transmission band becomes. Method according to one of Claims 1 to 3, characterized in that the sum (S) of the respective frequency bandwidths of the subchannels (F _subchannel ) and the frequency bandwidth of the frequency transmission _band (F _{U band} ) determines and the maximum, equidistant frequency band spacing (F _distance ) between the frequency edges of the respectively adjacent subchannels is calculated according to the following equation:

Method according to one of the claims 1 to 4, characterized in that at the same time sending digital and analog data over different subchannels, to the frequency edges the respectively adjacent subchannels with digital data transmission a maximum and to the frequency edges of each adjacent subchannels with analog data transmission a minimum frequency band gap is maintained. Method according to one of the claims 1 to 5 characterized in that in the respective subchannels language or transfer data can be. Method according to one of the claims 1 to 6, characterized in that the data utilization of the subchannels during a transmission several times checked and depending the data utilization, the assignment of the subchannels with respect to their position and / or Width in the frequency transmission band changed becomes. Use of the method according to one of claims 1 to 7 for data transmission via cable lines, in particular high voltage power lines.