WO2002103971A2 - Multicarrier receiver - Google Patents

Abstract

The invention relates to a method for transmitting an analog data flow (101). According to said method, transients are compensated when the analog data flow is received, by transforming the analog data flow (101) into a digital data flow (103) by scanning the analog data flow (101) in an analog-digital converter (104), the digital data flow is then equalised in the temporal region in an equalisation device (105), the equalised digital data flow (106) is decimated in a decimation device (107) in order to obtain a decimated equalised digital data flow (109), the temporal region is transformed into the frequency region by means of a transformation device (110), transformation signals obtained (111a - 111n) are corrected in a correction device (112), at least one value signal (114) and at least one phase signal (115) are determined in a determination device (116), and the value signals (114) and the phase signals (115) are decoded in a decoding device (117), in order to obtain a decoded data flow (118) and to output the same by means of a data output device (119).

Description

description

Method for transmitting an analog data stream and circuit arrangement

The present invention relates to a method for transmitting an analog data stream and a circuit arrangement, and in particular relates to a method for transmitting an analog data stream, in which transients are compensated for when the analog data stream is received, and a circuit arrangement with an optimized equalization device for the time domain in the case of multiple tones. transmission method.

In a conventional manner, a multiple-tone method (DMT, Discrete Multitone, Discrete Multi-tone Modulation) is used for asymmetrical data stream transmission via ordinary telephone lines, whereby ordinary telephone lines are usually designed as asymmetrical digital subscriber lines (ADSL = asymmetry digital subscriber line).

A major advantage of ADSL transmission techniques is that conventional cable networks can be used for transmission, usually using copper twisted pairs.

State-of-the-art digital high-speed subscriber lines are described, for example, in the publication “High-speed digital subscriber lines, IEEE Journal Sei. Ar. In Comm. , Vol. 9, No. August 6, 1991.

Among the transmission methods with a high data rate on the basis of digital subscriber lines (DSL = Digital Subscriber Line) several VDSL (Very High Data Rate DSL) arrangements are known, for which purpose methods such as CAP (Carrierless Amplitude / Phase ), DWMT (Discrete Wavelet Multitone), SLC (Single Line Code) and DMT )>to> - ¹ μ »cπ O π o LΠ o Cπ

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otherwise, there will be a disadvantageous reduction in transmission capacity.

In the ADSL standard, for example, a DMT symbol length of N = 64 and a value of a cyclic prefix of M = 4 are provided for data transmission from a subscriber to an exchange. In order to limit a transient process to the cyclic prefix, in the known method in the preprocessing device, which is arranged in the data stream receiver, a special equalization device for the time domain (TDEQ = Time Domain Equalizer) is provided in the form of an adaptive transversal filter, which is provided with a sampling rate Fs works (for example 276 kHz in the exchange at ADSL).

Due to the necessary limitation of the length of the cyclic prefix to, for example, M = 4, as mentioned above, a transmission quality is disadvantageously deteriorated in conventional methods for transmitting an analog data stream 101, since even when an equalization device is used in the data stream receiver, a considerable inter-symmetry bolinterference (ISI) is present.

A conventional transmission channel furthermore disadvantageously contains high and low passes in order to limit the bandwidth of the analog data stream to be transmitted and to prevent out-of-band noise in analog-digital and digital-analog converters, which are designed, for example, as sigma-delta converters can be suppress.

In particular, it is disadvantageous that when low-pass filters are excited with DMT signals, transient processes occur which have considerable spectral components in a frequency range above the intended transmission signal band. At a sampling rate Fs of, for example, 276 kHz, folded products in the transmission signal band result in spectral components which cannot be eliminated by the equalization device arranged in the data stream receiver, ie by the time domain equalizer.

These folded products are disadvantageously contained as interference signals in the transmission signal band, as a result of which a transmission quality is deteriorated.

It is therefore an object of the present invention to provide a method for transmitting an analog data stream, in which transient processes are compensated for when the analog data stream is received, in particular an equalization device which is arranged in the data stream receiver for the analog data stream, that spectral components caused by the band limitation in a conventional transmission channel do not occur in the transmission signal band.

This object is achieved by the method specified in claim 1 and by a circuit arrangement with the features of claim 9.

Further embodiments of the invention result from the subclaims.

An essential idea of the invention is that, in order to compensate for transient processes when an analog data stream is received, the analog data stream converted in an analog-digital converter is equalized immediately after the analog-digital converter in order to provide an equalized digital data stream, whereby the equalized digital data stream is then decimated in a decimation device. It is therefore an advantage of the method for transmitting an analog data stream according to the present invention that convergence in an equalization device is improved, as a result of which convolution of high-frequency components in the transmission signal band is avoided.

It is also expedient that the method according to the invention provides an increased data transmission rate.

The method according to the invention for transmitting an analog data stream essentially has the following steps:

a) receiving the analog data stream via a transmission channel which has high and low pass filter devices for band limitation, the analog data stream being further processed in a data stream receiver;

b) converting the received analog data stream into a digital data stream by sampling the analog data stream at a sampling rate which is provided by an analog-digital converter;

c) equalization of the analog data stream converted in the analog-digital converter in the time domain in an equalization device in order to obtain an equalized digital data stream;

d) decimating the equalized digital data stream output by the equalizing device in a decimation device in order to obtain a decimated equalized digital data stream;

e) transforming the decimated equalized digital data stream from the time domain to the frequency domain in one

Transformation device 110 to obtain transformation signals, which are defined in magnitude and phase, wherein the transformation device provides, for example, a fast Fourier transformation (FFT = Fast Fourier Transformation);

f) correcting the transformation signals in a correction device in order to obtain corrected transformation signals which are weighted, for example, with an inverse transfer function of the transfer channel;

g) determining at least one magnitude signal and at least one phase signal from at least one corrected transformation signal in a determination device;

h) decoding the at least one magnitude signal determined in the determination device and the at least one phase signal in a decoding device in order to obtain a decoded data stream; and

i) outputting the decoded data stream via a data output device.

Advantageous developments and improvements of the respective subject matter of the invention can be found in the subclaims.

According to a preferred development of the present invention, the analog data stream contains multiple-tone signals which are processed in such a way that a frequency spectrum of 4.3 kHz to 1.1 MHz is formed by 256 individual sine tones which can be modulated in magnitude and phase.

According to a further preferred development of the present invention, the analog data stream is sampled at a sampling rate which is above a symbol rate down to the symbol rate. According to yet another preferred development of the present invention, the digital data stream is equalized in the equalization device at a rate which is above a symbol rate.

According to yet another preferred development of the present invention, the rate at which the digital data stream is equalized in the equalization device has a value which corresponds approximately to the value of the sampling rate at which the received analog data stream is sampled.

According to yet another preferred development of the present invention, decimation of the equalized digital data stream is suppressed, as a result of which a further increase in the quality of transmission is provided, with an increased signal processing effort in the transformation device, which, for example, carries out a fast Fourier transformation, must be provided.

According to yet another preferred development of the present invention, the transformation signals are weighted with an inverse channel transmission function of the transmission channel in a correction device in order to obtain corrected transformation signals.

According to yet another preferred development of the present invention, a pair of transformation signals formed on a magnitude signal and a phase signal is provided by a determination device after an evaluation of the corrected transformation signals.

The circuit arrangement according to the invention for transmitting an analog data stream also has:

a) a transmission channel for transmitting the analog data stream from a data stream transmitter to a data stream receiver; b) an analog-digital converter arranged in the data stream receiver for converting the received analog data stream into a digital data stream, in which the analog data stream is sampled at a sampling rate;

c) an equalization device for equalizing the digital data stream in the time domain in order to provide an equalized digital data stream;

d) decimation means for decimating the equalized digital data stream to provide a decimated equalized digital data stream;

e) a transformer for transforming the decimated equalized digital data stream from the time domain to the frequency domain to provide transformation signals defined in magnitude and phase;

f) a correction device for correcting the transformation signals in order to provide corrected transformation signals;

g) a determination device for determining at least one magnitude signal and at least one phase signal from at least one corrected transformation signal;

h) a decoding device for decoding the at least one magnitude signal and the at least one phase signal determined in the determination device in order to provide a decoded data stream; and

i) a data output device for outputting the decoded data stream. Embodiments of the invention are shown in the drawings and explained in more detail in the following description.

The drawings show:

1 shows a data stream receiver for receiving an analog data stream according to an embodiment of the present invention;

Figure 2a is a block diagram of a DMT transmission link

Data stream transmitter, transmission channel and data stream receiver;

FIG. 2b shows a schematic structure of a DMT symbol with a cyclic prefix;

FIG. 3 shows the transmission arrangement illustrated in FIG. 2a for transmitting an analog data stream in a more detailed representation; and

Figure 4 shows a conventional data stream receiver.

In the figures, identical reference symbols designate identical or functionally identical components or steps.

Figure 1 shows an embodiment of a DMT data stream receiver according to the present invention. An analog data stream 101, which has been transmitted via a transmission channel 102, which may be subjected to noise, is fed to an analog-to-digital converter which samples the analog data stream 101 at a sampling rate 108. Here, an equidistant sampling of the analog data stream 101 can take place. The analog-to-digital converter 104 converts the transmitted analog data stream 101, which is superimposed with a noise signal 122, into a digital data stream 103 which is used by a pre-decimation device 107a is fed. In the pre-decimation device 107a, the digital data stream 103 is pre-decimated in one or more decimation stages, one or more decimation stages also being provided in a subsequent decimation device 107 (described below).

The data stream output by the pre-decimation device 107a is then fed to an equalization device 105.

The equalization device 105 works in the time domain, wherein the equalization device 105 is supplied with a symbol rate 120, with which an equalization in the time domain is provided. The equalization device 105 preferably operates in the time domain with a higher sampling rate than the symbol rate 120.

It should be pointed out that the equalization device 105 is operated at an adjustable rate, wherein the symbol rate 120 of the equalization device 105 corresponds at most to the sampling rate 108 of the analog-digital converter 104. The equalized digital data stream 106 output by the equalization device 105 is fed to a decimation device 107, in which the equalized digital data stream 107 is decimated.

Furthermore, it is possible for the decimation device 107 to be integrated in the equalization device 105 in order to form an optimized time-domain equalization.

Furthermore, decimation can be completely suppressed, which means that in the subsequently required transformation device an increased effort with regard to a fast Fourier transformation is required. A decimated, equalized digital data stream 109, which is provided by the decimation device 107, becomes one o co to M μ ¹ μ ^

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FIG. 2a shows a basic block diagram of an arrangement for transmitting an analog data stream according to the DMT method, the data stream transmitter 210, the transmission channel 102 and the data stream receiver 211 being illustrated.

Data stream transmitter 210 and data stream receiver 211 consist of separately identifiable blocks, which are briefly described below. A data input device 201 serves to input data to be transmitted, the input data being forwarded to a coding device 202. In the coding device 202, the data stream is decoded in accordance with a conventional method and fed to a reverse transformation device 203.

The reverse transformation device 203 provides a transformation from the data present in the frequency domain into data which are available in the time domain. The reverse transformation device 203 can be provided, for example, by a device in which an inverse fast Fourier transformation (IFFT = Inverse Fast Fourier Transformation) is carried out.

It should be pointed out that the transformation carried out in the reverse transformation device 203 from the frequency domain into the time domain represents a transformation inverse to the transformation carried out by the transformation device 110 shown in FIG. 1.

Finally, the digital data stream output by the reverse transformation device 203 is converted into an analog data stream by means of a digital-to-analog converter 204. The analog data stream now present in the time domain is fed to a transmission channel 102 which provides the data transmission described above, whereby at a transmission a bandpass, highpass and / or low-pass filtering as well as an exposure to the analog data stream 101 with noise. The analog data stream 101 is further fed to the analog-to-digital converter 104 arranged in the data stream receiver 211, which converts the received analog data stream 101 into a digital data stream 103, the converted digital data stream 103 being fed to the transformation device 110.

After a transformation from the frequency domain into the time domain inverse to that in the inverse transformation device 203, after the transformed data stream has passed through a correction device (not shown) and a determination device (not shown), decoding takes place in the decoding device 117. The decoded data stream becomes finally output via the data output device 119.

FIG. 2b shows a diagram of a discrete multi-tone symbol, the analog data stream to be transmitted being provided as a sequence of multi-tone symbols. Before the data transformed in the transformation device 203 is passed on to the digital-to-analog converter 204, the last M samples of a multiple-tone symbol are appended to the beginning of the block, as a result of which a cyclic prefix is defined and the following applies:

M <N

In this way, a periodic signal can be simulated for a data stream receiver when the transient caused by the transmission channel has decayed after M samples, i.e. no intersymbol interference (IST.) Occurs.

As shown in FIG. 2b, the original multi-tone symbol has a length of N samples, for example N = 64 while, for example, the last four values are set as a cyclic prefix 212 to the DMT symbol beginning 205, where:

M = 4.

The total length of a multi-tone symbol 208 with the DMT symbol end values 213 appended to the symbol start 205 is now M + N from the prefix start 207 to the DMT symbol end 206.

It should be noted that the number of DMT symbol end values 213 which are cyclically attached to the symbol start 205 must be kept as small as possible, i.e. M «N in order to obtain the smallest possible reduction in the transmission capacity and quality.

In another example, a multi-tone symbol 208 consists of 256 complex numbers, which means that 512 time samples (real and imaginary part) have to be transmitted as a periodic signal. In this example, if a number of 32 DMT symbol end values 213 are copied to the beginning of the symbol as a cyclic prefix 212, a total length of the time sample to be transmitted is 544, which results in a sampling time T _A at a maximum audio frequency of a DMT signal of 2.208 MHz of 544 x 10 ^"6 / 2.208 sec or 0.25 ms, the symbol transmission frequency being calculated from f _DMT = 1 / T _a » 4 kHz.

FIG. 3 shows a method for transmitting an analog data stream and a circuit arrangement in more detail.

The data stream supplied to the data input device 201 is combined into blocks, a specific number of bits to be transmitted being assigned to a complex number depending on the level. In the coding device 202, Finally, coding follows in accordance with the selected level, the coded data stream finally being fed to the inverse transformation device 203.

Finally, a multiple-tone signal 303 provided by the reverse transformation device 203 forms a digital transmitter data stream which has been transformed from the frequency domain into the time domain. The multi-tone signal 303 embodied as a digital data stream is finally converted into an analog data stream in the digital-to-analog converter 204 and fed to a line driver device 304.

The line driver device 304 amplifies or drives the analog data stream 101 to be transmitted into a transmission channel 102, the channel transmission function of which is known in principle or can be measured. The analog data stream is also overlaid with noise in the transmission channel, which is shown in FIG. 3 by an overlay device 121. The superimposition device 121 is supplied with the analog data stream transmitted by the transmission channel and a noise signal 122, so that finally an analog data stream 101 superimposed with noise is obtained.

The analog data stream 101 is fed to a preprocessing device 301 which, according to the invention, contains the analog-to-digital converter 104 shown in FIG. 1, the equalization device 105 and the decimation device 107 in the order shown in FIG. 1.

A preprocessed digital data stream 302 output by the preprocessing device 301 is finally fed to the circuit units of the data stream receiver 211, which have already been described with reference to FIG. 1. The description of the components of the data stream receiver 211 shown in FIG. 3 are thus omitted here in order to avoid an overlapping description. However, it should be pointed out that decimation of the equalized digital data stream 106 can be suppressed, in which case the transforming device 110 must be capable of being subjected to a correspondingly higher rate, thereby achieving the advantage that a further improvement in the transmission quality is provided.

With regard to the conventional circuit arrangement for receiving an analog data stream 101 shown in FIG. 4, reference is made to the introduction to the description.

Although the present invention has been described above on the basis of preferred exemplary embodiments, it is not restricted to these but can be modified in a variety of ways.

LIST OF REFERENCE NUMBERS

In the figures, identical reference symbols designate identical or functionally identical components or steps.

101 Analog data stream

102 transmission channel

103 Digital data stream

104 analog-to-digital converters

105 equalizer

106 Equalized digital data stream

107 decimation device 107a pre-decimation device

108 sampling rate

109 Decimated equalized digital data stream

110 transformation device purple - transformation signals Hin

112 correction device

113a corrected transformation signals 113n

114 amount signal

115 phase signal

116 determination device

117 decoder

118 Decoded data stream

119 Data output device

120 symbol rate

121 overlay device

122 noise signal

201 data entry device 202 coding device

203 reverse transformation device

204 digital-to-analog converter

205 DMT symbol start

206 DMT symbol end

207 Prefix start

208 Discrete multi-tone symbol ("DMT symbol")

210 stream transmitters

211 Data stream receivers

212 Cyclic prefix

213 DMT symbol end values

301 preprocessing device

302 Pre-processed digital data stream

303 multi-tone signal

304 line driver device

401 First filtering device

402 Second filtering device

Claims

claims 1. A method for transmitting an analog data stream (101), settling processes being compensated for when the analog data stream (101) is received, with the steps: a) receiving the analog data stream (101) via a transmission channel (102) in a data stream receiver; b) converting the received analog data stream (101) into a digital data stream (103) by sampling the analog data stream (101) at a sampling rate (108) in an analog-digital converter (104); c) equalizing the digital data stream (103) in the time domain in an equalization device (105) in order to provide an equalized digital data stream (106); d) decimating the equalized digital data stream (106) in a decimation device (107) to provide a decimated equalized digital data stream (109); e) transforming the decimated equalized digital data stream (109) from the time domain into the frequency domain with a transformation device (110) to provide transformation signals (purple-Hin) which are defined in magnitude and phase; f) correcting the transformation signals (llla-llln) in a correction device (112) to provide corrected transformation signals (113a-113n); g) determining at least one magnitude signal (114) and at least one phase signal (115) from at least one corrected transformation signal (113a-113n) in a determination device (116); h) decoding the at least one magnitude signal (114) determined in the determination device (116) and the at least one phase signal (115) in a decoding device (117) in order to provide a decoded data stream (118); and i) outputting the decoded data stream (118) via a data output device (119). 2. The method for transmitting an analog data stream (101) as claimed in claim 1, which means that the analog data stream (101) contains multiple-tone signals (303). 3. A method for transmitting an analog data stream (101) according to one or both of claims 1 and 2, characterized in that the analog data stream (101) is sampled at a sampling rate (108) which is above a symbol rate (120) down to Symbol rate (120). 4. A method for transmitting an analog data stream (101) according to one or more of claims 1 to 3, characterized in that the digital data stream (103) in the equalization device (105) with a above the symbol rate (120) and close to the sampling rate ( 108) lying rate is equalized. 5. A method for transmitting an analog data stream (101) according to one or more of claims 1 to 4, characterized in that a decimation of the equalized digital data stream (106) is suppressed, whereby a higher transmission quality is provided. 6. A method for transmitting an analog data stream (101) according to one or more of claims 1 to 5, characterized in that a fast Fourier transform (FFT) is used to transform the decimated, equalized digital data stream (109) from the time domain to the frequency domain , 7. The method for transmitting an analog data stream (101) according to one or more of claims 1 to 6, characterized in that for correcting the transformation signals (llla-llln) in a correction device (112) to corrected transformation signals (113a-113n) to provide, the transformation signals (llla-llln) are weighted with an inverse channel transfer function of the transfer channel (102). 8. A method for transmitting an analog data stream (101) according to one or more of claims 1 to 7, characterized in that when the at least one magnitude signal (114) and the at least one phase signal (115) are determined from at least one corrected transformation signal (113a) 113n), a transformation signal pair formed from a magnitude signal (114) and a phase signal (115) is provided in a determination device (116). 9. Circuit arrangement for the transmission of an analog data stream (101), with: a) a transmission channel (102) for transmitting the analog data stream (101) from a data stream transmitter (210) to a data stream receiver (211); b) an analog-digital converter (104) arranged in the data stream receiver (211) for converting the received analog data stream (101) into a digital data stream (103) by sampling the analog data stream (101) at a sampling rate (108); c) an equalization device (105) for equalizing the digital data stream (103) in the time domain in order to provide an equalized digital data stream (106); d) decimation means (107) for decimating the equalized digital data stream (106) to provide a decimated equalized digital data stream (109); e) a transformation device (110) for transforming the decimated equalized digital data stream (109) from the time domain into the frequency domain to provide transformation signals (llla-llln) which are defined in magnitude and phase; f) a correction device (112) for correcting the transformation signals (llla-lln) in order to provide corrected transformation signals (113a-113n); g) a determination device (116) for determining at least one magnitude signal (114) and at least one phase signal (115) from at least one corrected transformation signal (113a-113n); h) decoding means (117) for decoding the at least one magnitude signal (114) and the at least one phase signal (115) determined in the determination means (116) in order to provide a decoded data stream (118); and i) a data output device (119) for outputting the decoded data stream (118). 10. Circuit arrangement for transmitting an analog data stream (101) according to claim 9, characterized in that the decimation device (107) is formed integrally with the equalization device (105) in such a way that equalization is provided in the equalization device (105) and decimation in the decimation device (107) at a uniform rate. 11. Circuit arrangement for transmitting an analog data stream (101) according to one or both of claims 9 and 10, characterized in that for correcting the transformation signals (llla-llln) in a correction device (112) in order to provide corrected transformation signals (113a-113n), the correction device (112) is designed as a frequency domain equalization device. 12. Circuit arrangement for the transmission of an analog data stream (101) according to one or more of claims 9 to 11, characterized in that when a decimation of the equalized digital data stream (106) is suppressed, a transformation device (110) is designed such that it is connected to a Equalization can be applied in the higher rate corresponding to the equalization device (105), so that a higher transmission quality is provided.