WO2000013362A1 - Method and device for adapting a transmission data rate or a transmitter power to the transmission quality of a transmission channel - Google Patents

Abstract

The aim of the invention is to adapt a transmission data rate to an existing transmission channel. To this end, the invention provides that the transmitter power and/or the coding method is/are selected in such a way that a maximally possible transmission data rate or minimal transmitter power can be used according to the transmission quality of the transmission channel.

Description

description

Method and device for adapting a transmission data rate or a transmission power to the transmission quality of a transmission channel

The invention relates to a method for adapting a transmission data rate or transmission power to the transmission quality of a transmission channel.

The need for digital transmission systems has skyrocketed in recent decades. Digital transmission systems are generally structured in the functional units shown in FIG. 1. A message source 1 generates information which is transmitted from a transmitter to a receiver via a transmission channel 4. The properties of the information to be transmitted depend on the message source. Messages to be transmitted can be, for example, an audio signal or a video signal. Analog transmission systems transmit analog signals that were generated by analog message sources directly via the transmission channel using conventional analog modulation methods. Such modulation methods are e.g. the amplitude modulation, the frequency modulation or the

Phase modulation. In digital transmission systems, the information to be transmitted is converted into a sequence of binary digits. In order to make the best possible use of the capacity of the channel, the message to be transmitted should be represented with as few binary digits as necessary. For this purpose, a source encoder is used, which has the task of converting and encoding the messages to be transmitted in a sequence of signal values so that the channel can transmit them. The source encoder tries to transmit the messages to be transmitted in binary as efficiently as possible Convert digits.

The sequence of binary digits generated by the source encoder is transmitted from the channel to the receiver. Such an actual channel can, for example, consist of a

Line connection, a coaxial cable, an optical fiber (LWL), a radio link, a satellite channel or a combination of these transmission media. Such channels cannot directly transmit the sequence of binary digits from the transmitter. To do this, the sequence of digital information must be converted into m signal values that correspond to the properties of the channel. Such a device is called a digital modulator. Such a modulator is part of the channel encoder 3, which additionally comprises a discrete channel encoder in order to provide the information to be transmitted with an error protection adapted to the channel.

The transmission channel 4 is not presupposed to work without errors, but it is assumed that a disturbance source 5 changes the transmitted signals with a certain probability during the transmission.

Such interference can be, for example, a crosstalk of signals that are transmitted on adjacent channels. The disturbances can also be caused by thermal

Noise is generated which is generated in the electronic circuits, such as amplifiers and filters, which are used in the transmitter and the receiver. In the case of cable connections, interference can also be caused by switching and in the case of radio or satellite connections by weather influences such as thunderstorms, hail or snow. Such influences change the transmitted signal and cause errors in the received digital signal sequence. In order to nevertheless ensure a relatively reliable transmission, the channel encoder increases the redundancy of the (binary) sequence to be transmitted. With the help of this redundancy added by the transmitter, the receiver is supported in decoding the information-carrying signal sequence. For this purpose, for example, the channel encoder combines a certain number of signals into blocks and adds a number of control signals (in the simplest case a parity bit). In this way, k information bits are always coded simultaneously, each k-bit sequence being assigned to a unique n-bit sequence, the so-called code word. The redundancy added in this way can be specified by the ratio n / k. This also corresponds to the channel bandwidth, which must be increased accordingly in order to transmit the information sequence expanded by the added redundancy.

Alternatively, increased reliability against channel interference can also be achieved, for example, by increasing the transmission power. However, since the increase in the transmission power is relatively expensive, the reliability by increasing the erforder ^¬ union channel bandwidth is m usually in verfugbarer bandwidth achieved.

When transmitting always one bit with the data rate R bit / s, the modulator assigns the binary number 0 a signal curve or a signal value (hereinafter referred to only as a signal value) s _η (t) and the binary number 1 a signal value s ₂ (t). This transmission of every single bit by the channel encoder is called binary modulation.

Alternatively, the modulator can transmit k information bits simultaneously using M = 2 ^1, different signal values s, (t) with ι = 1, 2, ... M, each of the 2 ^V possible k-bit sequences being assigned to a signal value . On the receiver end of a digital transmission system, the digital demodulator processes the (ev. Changed ^¬ changed) in the channel transmitted signal value and assigns to each signal value is a single number to which represents an estimate of the transmitted data symbol (eg binar).

After receiving a signal in the receiver, the demodulator must decide which of the M possible signal values has been sent. This decision is made in a decision maker (slicer), the decision should be made with minimal probability of error. This decision maker assigns a (usually prepared) reception value to one of the M possible symbol values.

For example, if binary modulation is used, the demodulator must decide when processing each received signal whether the bit being transmitted is a zero or a one. In this case the demodulator makes a binary decision. Alternatively, the demodulator can also make a ternary decision, the demodulator deciding for "zero", "one" or "no decision" depending on the quality of the received signal.

The decision process of a demodulator can be viewed as quantization, in which binary and ternary decisions are special cases of demodulation that quantizes Q levels, where Q> 2. In general, digital communication systems use high-quality modulation, where m = 0.1 ... M-1 represents the M-possible symbols transmitted.

If the transmitted information contains no redundancy, the demodulator must decide in each predetermined time interval which of the M signal values has been transmitted. Contains the transmitted information, however the redundancy, the demodulator reconstructs the original information ^¬ sequence due to the channel coder used by the code and the redundancy of the received data. Depending on the requirements determined by the applications, the channel encoder generates signal blocks that allow the channel decoder to either only determine whether certain faults have occurred (error-recognition coding) or even to correct errors caused by faults (up to a certain maximum number per signal block) (error correcting coding).

The error rate represents a measure of the reliability with which messages are transmitted from the sender to the receiver. The error rate indicates the average probability with which a bit error occurs

Output of the decoder occurs. The bit error rate indicates the number of error bits occurring at the receiver divided by the total number of bits received per unit of time. The bit error rate (or symbol error rate when assessing the error frequency of symbols) is the most important quality criterion of a digital transmission system. In general, the probability of error depends on the code properties, the type of signal values used to transmit the information about the channel, the transmission power, the properties of the channel, ie the strength of the noise, the type of interference, etc., and the demodulation and decoding processes. The significance of the bit error rate for digital transmission systems corresponds to that of the signal-to-noise ratio (SNR) of analog transmission systems.

The error rates with which symbols appear at the output of the demodulator or bits at the output of the decoder are dependent on the properties of the transmission medium, ie of the transmission medium. channel, depending on the chosen modulation and coding scheme and on the average power of the transmission signal. To adapt a transmission data rate to a transmission channel, the transmission properties of the transmission channel are conventionally determined by transmitting a bit or symbol sequence known to the receiver. The error rate of the channel can be determined in the receiver by means of a target / actual comparison. In this way, the goodness of the current data transmission can be determined. A disadvantage of this method, however, is that only the measurement can be measured extraction process of a possible combination of transmission power, coding and Modula ^¬. Thus need not be performed for each possible data rate or transmit power of its own measurement of finding an optimum Ubertragungsdatenrate or transmit power are typically itera m ^¬ used tive method.

The object of the invention is to provide an improved method or an improved device for adapting the transmission data rate and / or the transmission power to the transmission channel.

This task is for a device with the technical

Teaching of claims 1 and 9 and for a method with the technical teaching of claims 10 and 17 solved.

Advantageous embodiments of the invention are specified in the subclaims.

According to the invention, a transmission data rate or a

Transmission power m is set as a function of the measured signal-stor distance of the transmission channel. The maximum possible data throughput can be determined by measuring the transmission quality, in particular the signal-stor distance, of the transmission channel and accordingly a transmission / Diffraction data rate specified or the transmitted power are m Depending ^¬ ness minimized by the use Ubertragungsdatenrate.

In this way the Ubertragungssequenz from modulator Ubertragungs- channel demodulator "Online" (ie, during the Datenübertra ^¬ supply) can be independent of a chosen coding ^¬ be measured process and the transmission power and / or the coding method m depending on the required data transmission rate be set so that a predetermined bit or symbol error rate is guaranteed. The measurement of the signal-Stor-distance is a prerequisite to an encoding method defined so that the maximum possible data throughput can be found for a maximum tole ^¬ rierbare error rate and to determine for a fixed transmission rate, the minimum transmission power so that a maximum tolerable error rate is not exceeded. It is advantageous in particular that, measured for finding an encoding method that, based on the current Ubertragungs- channel and the modulation method used, the maximum possible transmission rate allowed, a single measurement from ^¬ is sufficient, whereas herkommlicherweise Ede possible combination of transmission power, coding and modulation method must become. It follows that the data rate can be changed without interruption ("soft switch") as long as the modulation scheme used is maintained.

In addition, the power of the transmitter can be adapted to the required transmission quality by increasing or reducing the transmission power as a function of a difference between the measured signal-stor distance and the required signal-stor distance. In this way, the transmission power can be optimally based on a measurement of the signal-stor distance, that is to say the lowest possible transmission power while at the same time guaranteeing the quality requirements and Compliance with the required transmission rate can be adapted to the selected transmission method and the existing transmission channel, ie minimized. The Stor emissions are minimized and at the same Übertragungska ^¬ is capacity of neighboring systems that operate on the same frequency ^¬ band, increases.

Preferred embodiments of the invention will be explained by reference to the drawing ^¬ standing. Show it:

1 shows the general structure of a night transmission system,

Fig. 2 shows the structure of an inventive shaped Ubertragungs- system for adapting the data rate and the Modulationsver ^¬ driving to the transmission medium by receiver-end signal-Stor-distance measurement,

3 shows the structure of a transmission system according to the invention for adapting the transmission data rate, the modulation method and the transmission power to the transmission medium by means of the receiver-side signal-Stor distance measurement and

4 shows a diagram to illustrate the “power control” for setting a transmission power as a function of a measured and a used transmission quality.

In digital information transmission, information is between a news source (sender) and one

Transmitting the receiver via a transmission medium. Such a device, located between the transmitter and the receiver, is generally referred to as a channel.

For the transfer, the data to be transferred m Converted code words, which are adapted to the transmission properties of the message channel, in order to secure the data to be transmitted, inter alia, against transmission errors.

During the transmission, a character, which is generally referred to as a symbol in the signal space or channel symbol, is assigned in the transmitter by means of a reversibly unique functional assignment of a bit sequence. This symbol is then mapped to a signal curve assigned to this symbol (hereinafter referred to as signal value). The functional assignment of one or more symbols to a bit sequence in the transmitter is called coding or mapping, the mapping of one or more such symbols to a signal value is called modulation.

This picture sequence is reversed in the receiver. During the demodulation, the allocation that is a received signal to a symbol due to Distortion ^¬ gene or superimposed interference of the channel is not m the control can be performed without error, prepares the decoded more tion, that is, the transfer of a detected symbol, the corresponding bit sequence m with ease .

In FIG. 2, the construction of a transmission system is ones shown, provides that Nals sets a desired data rate to determine the quality of Ubertragungska ^¬. Digital information, in particular a bit sequence 13, is transmitted from a transmitter 10 via a transmission channel 11 to a receiver 12, which outputs the received digital information, in particular the bit sequence 25. The channel encoder 14 of the transmitter 10 contains a digital channel encoder 50, a bit / symbol converter 15 and a modulator 17. The digital channel encoder 50 adds redundancy to the incoming bit stream 13. The coded bit stream 51 thus formed is converted into a symbol sequence 16 in the bit / symbol converter 15 m, which in turn is reversibly and uniquely mapped onto a signal curve or signal values 18 by a modulator 17. The signal values 18 are transmitted to the receiver 12 via the transmission channel 11.

The channel decoder 20 of the receiver 12, the m is the receive ^¬ NEN signal values 19 converts a digital information 25 contains as an essential component a demodulator 55, a bit converter symbol / 24 and a digital channel decoder 52. In the demodulator the received signal values 19 are first processed by an analog and optional digital signal processing unit, which could include, for example, a reception amplifier, an A / D conversion and an equalizer. The so processed signal value 21 is then a slicer or decision leads 22 supplied ^¬, of each received signal value? 21 assigns a symbol 23.

The / bit converter 24 symbol of the channel decoder 20 arranged each detected symbol or each detected Symbolse ^acid sequence 23 according to the selected method Mappmg an encoded digital information and an encoded bit sequence to 53 from which by means of the digital channel Decoder 52 the digital information or the bit stream 25 is derived according to the selected coding method.

The decision maker (slicer) 22 is a fundamental component of every demodulator. Such a decision maker assigns the symbol or symbols that was most likely to be transmitted to a received value prepared in the rule. Since the set of input values of the decision maker does not generally correspond to the "valid" signal values of the transmitter due to interference or distortion of the transmission channel m, ie the signal values that are assigned to the symbols to be transmitted, the input signal 21 and the output 23 of the decision of the decider ^¬ applied signal-Stor-distance passage 28 regardless of the encoding and Mappmg algorithm are determined. For this purpose, a receiver according to the invention has a device 27 for measuring the signal-to-noise ratio (signal-to-noise ratio SNR) of the information transmitted via the transmission channel 11.

In one possible embodiment of a device for measuring the signal-to-storage distance, a signal value 60 is assigned to each detected symbol in the demodulator on the receiver side, which the decision-maker input in the demodulator had received if the signal curve or signal value corresponding to the detected symbol was undistorted would have been transferred. In this way, a hypothetical input signal is generated which corresponds to the detected symbol values and does not contain any signal values with channel distortions and interference. This reference signal corresponds - as long as the decision maker does not detect any wrong symbols - to the original signal on the transmitter side. The interference signal can be obtained by subtracting this reference signal from the processed receiver signal 21.

The average power of this reference signal formed in this way corresponds to the average power of the received, undisturbed signal component. The average power of the signal at the decision input corresponds to the total power of the received interference and signal component. From this, the interference power is calculated with the aid of the previously calculated undisturbed signal component. From the ratio of the average power of the undisturbed signal component to the average power of the interference component, the signal-to-interference distance (SNR) results as a measure of the transmission quality of the transmission channel. With such a method it is avoided that the receiver a certain transmit sequence must be known, as it is Joei walls ^¬ ren conventional methods necessary. In addition, the error rate is determined in parallel with the evaluation of the transmitted symbols, that is to say “online”. For the continuous measurement of the transmission quality, it is therefore no longer necessary to periodically intersperse a measurement sequence in the data stream to be transmitted. In this way, a reduction in the net data rate of the transmission channel can be avoided.

To ensure a great confidence a conventional method using a transmitter and are received, ^¬ ger known test sequence, a large number of errors must cover, usually a few hundred meters. For the generally required, very low bit error rates, for example 10 ^{^} the conventional methods very benotigen long measurement times, learning to a corresponding number of Feh ^¬ to detect. In contrast, the method according to the invention is based on the evaluation of the measured signal-stor distance during the ongoing transmission. However, since only considerably shorter measurement times are required for the evaluation of the average powers than for the comparable evaluation of the symbol or bit stream, the transmission quality can be determined much more quickly with the method according to the invention.

Depending on the coding and mapping method selected, there is always a clear functional relationship between the signal-to-memory distance 28 (also referred to as signal-to-noise ratio) and a symbol error rate or bit error rate. The signal-stor distance thus qualifies the transmission properties of the channel and the currently selected modulation or demodulation method, regardless of the coding or mapping method selected. Over a Measuring of the signal-Stor-distance 28 of a Ubertragungs ^¬ channel 11 can thus be the coding or the Mappmg method of the current modulation / demodulation method so Festge ^¬ specifies that a desired data throughput can be set for a still tolerable error rate . To this end, the determined signal to noise ratio 28 of a device 29 for determining a maximum data rate Ubertra ^¬ supply 30 and a coding and Mappmg method fed. The device 29 determines a dependency on the preferably m decibel (dB) determined signal-to-storage distance 28 according to a known connection, a coding and mapping method or a maximum transmission data rate 30 for the current modulation and demodulation method, which at the existing signal-stor distance 28 enables a maximum data throughput. As parameters of the conversion device 29 of the ^¬ characteristic the maximum tolerable error rate 61 and the modulation method 62 may occur. Depending on the measured transmission quality 28 of the transmission channel 11, and m depending on the current modulation / demodulation method 62 and m depending on a maximum permissible error rate in the transmission of the digital information 61, a coding scheme (code 1, code 2 ... Code 6) and Mappmg-Sche a (Map. 1 ... Map. 6) are selected, which, given the actual situation, enables a maximum data throughput for the current modulation / demodulation method with a predetermined reliability.

The device 29 can be arranged both in the receiver 12 and in the transmitter 10. In any case, either the determined signal-to-storage distance 28 or the determined maximum transmission data rate or the selected coding and mapping method 30 must be transmitted to the transmitter via a data connection 31. The information about the coding and mapping method, with which a maximum transmission data rate 30 can be achieved for the current modulation / demodulation method, is fed to a control device 33 in the transmitter. These control emrichtung selected on the basis of the maximum possible data ^¬ transmission rate and the digital to transmission information 13 are each required data transmission rate 32, a data transmission rate 34 tatsäch Lich used ^¬ from that to be fixed on en encoding, Mappmg- and modulation scheme is to be implemented. This information data rate on the one hand and / or coding, Mappmg- and modulation method other ^¬ hand - is both the corresponding components of the channel encoder 14 of the transmitter 10, such as encoder 50, bit / symbol converter 15 and modulator 17, as well as a Data link 35 is fed to the corresponding components of the channel decoder 20 of the receiver 12, such as demodulator 55, symbol / bit converter 24 and decoder 52.

The operation of the inventive Vorrich ^¬ processing at startup of the transmission system will be described. The measurement of a transmission system is conveniently carried out with the lowest possible transmission data rate (based on the respective modulation method) and with the maximum possible transmission power. In this way, a low symbol error rate is guaranteed, the prerequisite for a high quality of a receiver

Signal-Stor distance measurement is. In this case, the generally used adaptive methods for signal processing have the shortest settling times and the largest possible system range is achieved in relation to a maximum permissible error rate. For the determination of the

Coding and mapping method, which allows a maximum possible transmission data rate for the transmission channel (and the modulation method currently used), then only a single measurement is required. Should be made possible if the desired data rate over different Modula ^¬ tion process, it must be a measuring performed for each mög ^¬ Liche modulation scheme.

The operation of the transmission system according to the invention during system operation is described below. Advantage ^¬ way legally the measurement of the transmission channel "Online" is based upon the transmitted data stream. It is therefore not necessary to lower the net transmission data rate in order to implement a transmission channel measurement outside the user data. The measurement of the signal-stor distance of a transmission data rate actually used is sufficient to be able to assess the transmission quality with the aid of other coding or mapping regulations of the implemented transmission data rates. The system can therefore judge the transmission properties of other transmission data rates in advance on the basis of the signal-stor distance measurement carried out at a current data transmission rate. Repeated iterative measurement for different transmission data rates is no longer necessary insofar as the modulation method is not changed.

As long as a transmission data rate is changed only on the basis of a new coding regulation or mapping regulation and not on the basis of a changed modulation method, the adaptive methods used in the demodulator also remain in the steady state. A change of the data rate is therefore possible without interruption ("soft switchmg"). However, if the data rate is adjusted by changing the modulation scheme, the system must be re-calibrated and a "soft switch" is not possible.

In Fig. 2, an embodiment is described in which determination of the signal-stor distance on the receiver side determines the maximum possible transmission data rate and transmits it to the transmitting side, which in turn determines an actually used transmission data rate based on the desired and the maximum possible transmission data rate and forwards it to the corresponding components in the transmitter and receiver . In contrast, an exemplary embodiment is described in FIG. 3, which additionally controls the output power of the transmitter. The adjustment of the transmission power transmission method to the channel and to the desired Ubertra- to as "Power Control" designated ^¬ net. As far as Fig. 3 has the same devices as m Fig. 2 on ^¬ , these are provided with the same reference numerals. In this embodiment, the evaluation of empfanger- mutually determined place Ubertragungs-qualitat 28 of Ubertragungs ^¬ channel 11 on the transmitter side instead. For this purpose, the transmitter has a device 41 which, like the device 29 in FIG. 2, determines a coding scheme or a maximum transmission data rate of the transmission channel 11.

In addition to the transmission quality 28 determined by the receiver 12, which is forwarded to the transmitter via the data connection 40, the device 41 is also supplied with the data rate 32 required for the transmission of the digital information 13. On the basis of the maximum permissible error rate for the transmission of the respective digital information 13, a coding or mapping and modulation method with an actual transmission data rate 34 is selected. This selected transmission data rate 34 is, as in the embodiment described with reference to FIG. 2, forwarded to the channel encoder 14 and the channel decoder 20.

The signal values 44 generated by the modulator 14 are additionally sent in the transmitter 10 to a device 43 for regulating the Transmission power forwarded. The signal generated by the device 43 45 is then transmitted via the Ubertragungska ^¬ nal. 11 The minimum transmission power required for transmission is also determined by the device 41. The transmission power is determined is eistungssignal 42 Ubertragungssignalverstarker the leads 43 applied ^¬ a Sendel ^¬.

Depending on the difference between a measured transmission quality of the transmission channel 46 and 11 of a transmission quality 47 (tenrate with a Ubertragungsda ^¬ 34 and having a certain maximum allowable error rate) to the selected coding and modulation method Mappmg- and corresponds to a Adaptation of the transmission power of the transmission signal amplifier 43 causes. This means that if the determined transmission signal quality of the transmission channel 46 is above the required transmission quality 47, the transmission power is reduced accordingly. If the required transmission quality 47 is above the transmission quality of the transmitter, the transmission power must be increased.

In this second embodiment, the difference between the measured signal-to-storage distance 46 and that required to implement a specific transmission data rate provides

Signal-Stor distance 47 em Measure of the increase or decrease in the current transmit signal power. If the transmission power required to implement a specific transmission data rate cannot be provided by the transmission module, the transmission system can at best implement the currently maximum possible transmission data rate as the transmission data rate.

Such a system according to the invention for adapting a transmission system to the transmission channel used is particularly suitable for use with the "asymmetric digital subscriber lme" technology. This so-called ADSL technology makes as well as other XDSL technologies zubrmger tauglicn for data-intensive applications ago ^¬ tional copper telephone lines than Hochgeschwmdigkeits-. Gleichzei ^¬ tig remains the availability of the usual telephone voice ^¬ services on the same line received. Building on the existing cabling, such technologies provide data rates that exceed ISDN, for example, many times over. This removes the restrictions of the existing public information network, which was previously only suitable for the transmission of speech, text and graphics with a low resolution. With such technologies, the conventional copper cable telephone network becomes a powerful system that is suitable for the transmission of multimedia content to all households.

However, the use of conventional telephone lines means that a high amount of noise is bought, which increases the greater the distance to be bridged. The distance to be covered by such technologies is on average between 500 m and 6 km.

However, the noise component increases not only with increasing length but also due to crosstalk from neighboring lines. With the help of the adaptive inventions

With such a method, the transmission system can automatically measure and adapt to the quality of the existing transmission line.

Claims

claims

1. Device for adapting a transmission data rate to the transmission quality of a transmission channel (11) with

a Qualitatsmesser (27) for determining the quality Ubertragungs ^¬ (28) of the transmission channel (11) and

a determination device (29) for determining a maximum transmission data rate of the transmission channel (11) as a function of the determined transmission quality (28).

2. Device according to claim 1, characterized in that said determining means (29) the maximum Ubertra ^¬ diffraction data rate (28) m a function of a certain maximum allowable error rate determined.

3. Apparatus according to claim 1 or 2, characterized in that the determining device (29) for determining the maximum Uebertragungsdatenrate (28) em corresponding coding ^¬ method or mapping method determines.

4. Device according to one of claims 1 to 3, characterized in that the device additionally a selection device (33) for selecting a transmission data rate (34) m as a function of the maximum transmission data rate (30) determined by the determination device (29) and as a function of a specific one requested transmission data rate (32).

5. Device according to one of claims 1 to 4, characterized in that the selection means (33) for selecting the data rate Ubertragungs ^¬ (34) having a certain maximum allowable error rate em encoding method and Ahren Mappmgverf selects.

6. Device according to one of claims 1 to 5, d a d u r c h g e k e n n z e i c h n t that

the quality meter (27) determines the transmission quality (28) for different modulation methods,

said determining means (29) the maximum Ubertragungsda ^¬ tenrate (30) for each of the various modulation methods determined and

said selecting means (33) selects the extraction process additionally used Modula ^¬.

7. Device according to one of claims 1 to 6, so that the transmitter (10) for the transmission of digital information (13) via the transmission channel (11) contains:

a digital channel coding device (50) for coding the digital information, a bit / symbol converter 15 for displaying the digital information (13) in the form of symbols (16) and

a modulator (17) for mapping the symbols (16)

Signal values (18) for transmission via the transmission channel (11),

and that the receiver (12) contains: a demodulator (55) for converting received signal values (19) into detected symbols (23) and

a symbol / bit conversion (24) for converting the received symbol stream (23) m an encoded bit stream (53) and

a Decodieremπchtung (24) for displaying the detektier ^¬ th symbols (23) as detected digital information (25).

8. Device according to one of claims 1 to 7, d a d u r c h g e k e n n z e i c h n e t that the transmitter (10) additionally comprises:

an adjustable transmission signal amplifier (43) and

a control means (41) for raising or lowering the transmission power of Ubertragungssignalverstarkers (43) depending on a difference between that of the Quali ^¬ tatsmesser (27) determined transmission quality (46) of the transmission channel (11) and the transmission quality (47) for the used transmission data rate (34) with a certain maximum permissible error rate is required.

9. Device for adapting the transmission power for the transmission of digital information (13) via a transmission channel (11) with a quality meter (27) for determining a transmission quality (28) of the transmission channel (11), and

a control device (43) for raising or lowering the transmission power as a function of a difference between the transmission quality (46) determined by the quality meter (27) and a transmission quality (47) used for a transmission of the digital information (13) Transmission data rate (34) with a certain maximum permissible error rate is required.

10. Method for adapting a transmission data rate for the transmission of digital information (13) via a transmission channel (11) to the quality of the transmission channel (11) with the following steps:

Determining the transmission quality (28) of Ubertragungs ^¬ channel (11) and

Determination of a maximum transmission data rate (30) of the transmission channel (11) as a function of the transmission quality determined and the modulation method used (28).

11. The method as claimed in claim 10, so that the maximum transmission data rate (32) is additionally determined as a function of a specific maximum permissible error rate (61).

12. The method according to any one of claims 10 and 11, characterized in that in addition a Ubertragungsdatenrate (34), em Mappm- galgorithmus and em corresponding coding m depen ^¬ dependence on the determined by said determining means (29) maximum Ubertragungsdatenrate (30) of Ubertragungs ^¬ channel (11) and depending on a requested Uber ^¬ tragungsdatenrate (32) and a maximum toleπerbaren error rate (61) is selected.

13. The method according to any one of claims 10 to 12, characterized in that the transmission quality (28) is determined in each case for different lationsverfahren modu ^¬,

a maximum possible data rate (30) of the transmission channel (11) is determined for each modulation method and

the modulation method to be used is selected as a function of the maximum transmission data rate (30) determined for each modulation method.

14. The method according to any one of claims 10 to 13, characterized in that a transmission power for transmitting the digital information ^¬ tion (13) via the transmission channel (11) m depending on the difference between the determined transmission quality

(46) of the transmission channel (11) and the transmission quality (47), which is required for the set transmission data rate with a certain maximum permissible error rate, is increased or decreased.

16. The method according to any one of claims 10 to 15, so that the following steps are carried out to transmit the digital information (13):

Representation of the digital information (13) in the form of symbols (16),

Mapping the symbols (16) to signal values (18),

Transmission of the signal values (18) via the transmission channel (11),

Receiving the transmitted signal values (21), Detecting the received signal values (21) and mapping the detected signal values onto detected symbols (23) and converting the detected symbols (23) into detected digital information (25).

17. The method according to any one of claims 10 to 16, so that the signal-stor distance is determined as a measure of the transmission quality (28).

18. A method for adjusting a transmit power for the transmission of digital information over ^¬ (13) via a transmission channel (11) to the transmission quality of the transmission channel

(11) with the following steps:

Determining the signal-Stor-distance (46) of the Ubertragungs ^¬ channel (11),

Raising or lowering the transmission power m as a function of the difference between the determined signal-stor distance

(46) of the transmission channel (11) and the signal-stor distance

(47) the transmission data rate (34) used to transmit the digital information (13).