DE10220228A1 - Adaptive differential pulse-code modulation method, involves quantization of the prediction error on transmission side depending on weighting factor - Google Patents

Abstract

A method for adaptive differential PCM in which on the transmission side, a predictor (PS) predicts of the actual sampled value of an input signal (s) and the difference (e) between the actual value (s) and the predicted value (s') (prediction error) is formed and is transmitted to a receiver. Quantization of the prediction error (e) results on the transmission side depending on a weighting factor (1/g) which depends on the prediction error (e) and that on the receiver side the transmission side input signal is recovered by weighting of the received code word representing the prediction error with the inverse weighting factor (g) by addition of the sampled value predicted by the receiver side predictor (PE). An Independent claim is given for a circuit arrangement for differential pulse-code modulation (PCM).

Description

The invention relates to a method for adaptive differential pulse code modulation, being on the transmission side Predictor predicts the current sample value of an input signal and the difference between the actual current and the the predicted sample value - the so-called Prediction error - formed and transmitted to a recipient, being on the receiving end of one with the predictor predicted sample predicted on the transmit side is added to the received prediction error by the to win the actual current sample again.

The invention further relates to a circuit arrangement for differential pulse code modulation, being on the transmit side an input signal at the addition input of a subtractor whose output is connected to the input of a quantizer is connected, the output of the quantizer being connected to the Control input of a transmitter-side predictor and with the first Input of a transmitter-side adder is connected, the Output connected to the input of the transmitter-side predictor is, the output of the transmitter-side predictor with the Subtraction input of the subtractor and the second input of the transmitter-side adder is connected, the output of the quantizer with the first input of a receiver-side adder and with the control input of a receiver-side predictor, whose input is connected to the output and its output with the second input of the receiver-side adder is connected.

Adaptive differential pulse code modulation is one Pulse code modulation, similar to the Delta modulation not the current samples of an input signal, but the differences between two samples from one transmitter transmitted to a recipient.

On the transmission side, there is an adaptive as a predictor Prediction filter provided that the current sample of the Predicts input signals. In a subtractor, the Difference - the so-called prediction error - between the actual sample and that of the adaptive Prediction filter predicted sample formed. The prediction error is quantified and as a code word to the recipient side transmitted where one with the transmission-side prediction filter identical receiver-side adaptive prediction filter the same Samples predict like the transmit side adaptive Prediction. To the original actual sample to be won again in an adder by the Prediction error transmitted on the transmission side and that of predicted sample value on the receiver-side adaptive prediction filter added.

Due to the measure, instead of sampling values only differences between samples, between the actual sample and a sample predicted by a predictor transmitted, the data rate can be significantly reduced. While in conventional pulse code modulation about eight bits are required to quantify a sample, are sufficient for adaptive differential pulse code modulation three to four bits.

The adaptive differential pulse code modulation is e.g. B. for the modulation of band-limited input signals, such as. B. Telephone signals, particularly suitable.

It is therefore an object of the invention, a method and a Circuit arrangement for adaptive differential To design pulse code modulation so that the data rate is significant can be reduced and less than three to four bits per sample lies.

In procedural terms, this task is carried out with specified features solved.

In terms of circuitry, this task is performed with the in claim 7 specified features solved.

In the modulation method according to the invention, the prediction error is not quantized on the basis of a predetermined characteristic curve, but is carried out in a signal-adaptive manner, ie as a function of the prediction error itself. For this purpose, a weighting factor g is introduced, which determines the value of the code word generated. Before the quantification, the prediction error on the transmission side is weighted with the weight factor 1 / g. On the receiver side, the transmitter-side input signal is recovered by weighting the transmitted code word representing the prediction error with the inverse weight factor g and by adding the sample value predicted by the receiver-side prediction filter.

An embodiment of the method according to the invention provides proposes the weighting factor g as a function of Prediction errors gradually by incrementing by a constant or by multiplying by a constant greater than 1 is to increment or incrementally by decrementing by a constant or by multiplication by one Decrement constants that are less than 1.

Another embodiment of the invention The procedure provides for the incremental incremental Incrementing or decrementing the weighting factor g in Depending on the quantized prediction error.

A further exemplary embodiment of the method according to the invention provides that the code word representing and weighted to be transmitted and to be transmitted is determined from the current value of the weighting factor g and the amplitude A of the prediction error according to the following rule:

Z = min (Z _max , nearest_integer (A / g)) for A ≥ 0

Z = max (Z _min , nearest_integer (A / g)) for A <0,

where Z _max = 2 ^N-1 - 1 and Z _min = -2 ^N-1 .

N is the number of the coding for the amplitude A of Prediction error provided bits.

For amplitudes of the prediction error that are ≥ 0, the number Z is the minimum of the number Z _max and the next whole number of the quotient A / g.

For amplitudes of the prediction error that are <0, the number Z is the maximum of the number Z _min and the next whole number of the quotient A / g.

Whenever the code word Z _max or Z _min results, the weighting factor g is increased, e.g. B. in the manner already described by incrementing. If, on the other hand, the resulting number Z falls below a predeterminable threshold value, the weighting factor g is gradually decremented in the manner also described. In addition, as also already explained, the step size with which the weighting factor g is incremented or decremented can be increased or decreased depending on the quantized prediction error.

The code word Z is transmitted from the sending side to the receiving side, where it is evaluated. The amplitude A of the received prediction error results from the following formula:

A = g × Z

The weighting factor g is reduced on the receiver side the same regulation as on the transmission side with a generator generated, which is identical to the generator for generating the Weighting factor g is on the transmission side. Through this Measures can be taken on the transmission side amplitude A on the Recover the receiver side so that the signal to be transmitted, e.g. B. a voice or audio signal, entirely from the Prediction errors can be reconstructed.

Another embodiment of the invention provides that Input signal on the transmission side before subtraction with the to compress the predicted sample and analogously to it the sum signal from the prediction error on the receiver side and expand the predicted sample. Through the sender-side compression and receiver-side expansion a further reduction in the data rate is achieved.

The invention will now be illustrated with reference to one in the figure Embodiment of the invention Circuit arrangement described and explained in more detail.

The input signal ES is at the input of a compressor K, preferably a dynamic compressor, the output of which is connected to the addition input of a subtractor. The output of the subtractor SU is connected to the input of a controllable weighting unit G1, the output of which is connected to the input of a quantizer Q. On the transmission side, the output of the quantizer Q is connected to the input of a controllable weighting unit G2, the output of which is connected to the control input of a prediction filter PS provided as a predictor and the first input of an adder AS. The output of the prediction filter PS is connected to the subtraction input of the subtractor SU and the second input of the adder AS. A generator GS for generating a weighting factor 1 / g and a weighting factor g is connected to the quantizer Q. That output of the generator GS at which the weighting factor 1 / g can be removed is connected to the control input of the weighting unit G1, while that output of the generator GS at which the weighting factor g can be tapped is connected to the control input of the weighting unit G2.

The common connection point of the exit of the Quantizer Q and the input of the weighting unit G2 is on the Receiver side with the input of a weighting unit G3, of a generator GE connected to the control input of the Weighting unit G3 connected control output Weighting factor g generated, and with the control input one as Predictor provided prediction filter PE connected. The Output of the weighting unit G3 is with the first input an adder AE connected, the second input of which Output of the prediction filter PE and its output with the Input of the prediction filter PE and the input of a Expanders E, preferably a dynamic expander, connected is.

The transmission-side input signal ES is compressed in the dynamic compressor, from whose output signal s in the subtractor SU the prediction value s' generated by the prediction filter PS is subtracted. The output signal e of the subtractor SU is weighted in the weighting unit G1 with the weighting factor 1 / g and quantized in the quantizer Q. The output signal eq of the quantizer Q is weighted on the one hand in the weighting unit G2 with the weighting factor g in order to compensate for the weighting with the weighting factor 1 / g at the input of the quantizer Q. The unweighted output signal of the weighting unit G2 controls the prediction filter PS, which generates the prediction value s'.

On the other hand, the output signal eq of the quantizer Q on the receiver side also with the weighting factor g weighted to generate the unweighted prediction error to that in the adder AE that of the receiver Prediction filter PE, which with the transmitter prediction filter PS is identical, the generated prediction value s' is added. The Generator GE on the receiver side generates from the output signal eq of the transmitter-side quantizer has the weighting factor g, which controls the weighting unit G3. The output signal sq of the adder AE is expanded in the expander E in order to To generate output signal AL, which with the transmission side Input signal ES is identical.

The following 4 code words result for N = 2:
10, 11, 00 and 01,
that of a two's complement representation of the numbers
Z = - 2, -1, 0 and 1
correspond. Taking into account the weighting factor g, the amplitude of the coded prediction error results

A = g × Z.

As a result, A can have the following values:
A = -2 g,
A = -g
A = 0 and
A = g.

However, only the two's complement of the number Z of transmitted from the sender side to the receiver side, while the Weighting factors g in the generator GS and in the transmitter receiver-side generator GE derived from the prediction error become.

The invention is particularly suitable for the transmission of band-limited input signals, preferably telephone signals. Reference symbol list AE receiver-side adder
AL output signal
AS transmitter-side adder
e Subtractor output signal
E expander
eq output signal of the quantizer, weighted prediction error
ES input signal
g weight factor
GE receiver generator
GS transmitter-side generator
G1 weighting unit on the transmission side
G2 transmitter weighting unit
G3 weighting unit on the receiver side
K compressor
Q quantizer
s Compressed input signal
output recovered by adding the prediction error and the prediction value
SU subtractor
s' predictive value, predictive value.

Claims (9)

1. Method for adaptive differential pulse code modulation, a predictor (PS) on the transmission side predicting the current sample value of an input signal (s) and the difference (e) between the actual current sample value (s) and the sample value predicted by the predictor (PS) ( s ') - the so-called prediction error - is formed and transmitted to a receiver, the sample value (s') predicted by a receiver-side predictor (PE) identical to the predictor (PS) on the transmission side being added to the received prediction error (eq) on the receiver side is obtained in order to recover the actual current sample value, characterized in that the prediction error (e) is quantified on the transmission side as a function of a weighting factor 1 / g which depends on the prediction error (e), and that on the receiver side by weighting the Received code word (eq) representing the prediction error with the inverse weight factor g and by adding the sample value predicted by the receiver-side predictor (PE), the transmission-side input signal is recovered. 2. The method according to claim 1, characterized in that the Weight factor g as a function of the prediction error (e) gradually by incrementing by a constant or by multiplying by a constant that is greater than 1, is incremented or gradually by Decrement by a constant or by multiplying by a constant that is less than 1 is decremented. 3. The method according to claim 2, characterized in that the Step increment of incremental or Decrementing the weight factor g as a function of quantized prediction error occurs. 4. The method according to claim 1 or 2, characterized in that on the transmission side the amplitude of the prediction error (e) with a code word Z according to the regulation
Z = A / g
is coded, where g is the weight factor generated on the transmission side by means of a generator (GS) as a function of the amplitude A of the prediction error (e), that only the code word Z is transmitted to the receiver side, that on the receiver side by means of a with the generator ( GS) of the transmitter side of the identical generator (GE) the weight factor g is generated and the amplitude A of the prediction error (e) according to the regulation
A = g × Z
is recovered. 5. The method according to claim 3, characterized in that the Weight factor g with increasing amplitude A des Prediction error (s) increased, but decreasing is reduced. 6. The method according to any one of claims 1 to 5, characterized in that the code word Z is formed according to the following rule:
Z = min (Z _max , nearest_integer (A / g)) for A ≥ 0
Z = max (Z _min , nearest_integer (A / g)) for A <0,
where N = 2, 3, 4,. , , is the number of bits of the code word Z. 7. The method according to any one of claims 1 to 6, characterized in that the input signal (ES) on the transmission side before the difference is formed with the sample value (s') predicted by the predictor (PS) is compressed and that on the receiver side Addition of the prediction error (eq) and the prediction value (s') obtained output signal (sq) is expanded. 8. Circuit arrangement for differential pulse code modulation, with a receive signal (s) at the addition input of a subtractor (SU), the output of which is connected to the input of a quantizer (Q), the output of the quantizer (Q) being connected to the control input of a transmitter-side predictor (PS) and the first input of a transmitter-side adder (AS), the output of which is connected to the input of the transmitter-side predictor (PS), the output of the transmitter-side predictor (PS) being connected to the subtraction input of the subtractor (SU) and the second Input of the transmitter-side adder (AS) is connected, the output of the quantizer (Q) being connected to the first input of a receiver-side adder (AE) and to the control input of a receiver-side predictor (PE), the input of which is connected to the output and the output of which is connected to the second input of the receiver-side adder (AE), characterized in that the Input of a transmitter-side generator (GS) for generating a weight factor g and the inverse weight factor 1 / g is connected to the quantizer (Q) with that output of the transmitter-side generator (GS) at which the inverse weight factor 1 / g can be removed The control input of a first transmitter-side weighting unit (G1) located between the output of the subtractor (SU) and the input of the quantizer (Q) is connected to the output of the transmitter-side generator (GS) at which the weighting factor g can be removed from the control input A second transmitter-side weighting unit (G2) connected between the output of the quantizer (Q) and the first input of the transmitter-side adder (AS) is connected to the output of the quantizer (Q) with the input of a receiver-side generator (GE) for generating a weight factor g, which is identical to the transmitter-side generator (GS), is connected to the output of the receiver-side gene erators (GE), on which the weight factor g can be removed, is connected to the control input of a receiver-side weighting unit (G3), which between the common connection point of the output of the quantizer (Q) and the input of the second transmitter-side weighting unit (G2) on the one hand and the first input of the receiver-side adder (AE) on the other hand. 9. Circuit arrangement according to claim 8, characterized in that the input signal (Es) at the input of a Compressor (K) lies, whose output with the summation input of the subtractor (SU) is connected, and that the output of the receiver-side adder (AE) with the input of a Expanders (E) is connected, at the exit of which Output signal (AL) is removable.