DE2600386A1 - Speech signal transmission system - has dynamic compressor at the transmission side and a dynamic expander at the reception side - Google Patents

Abstract

The dynamic compressor has a differential amplifier (100), with the input signal applied to its one input (104). A first means (101, 102) generates a signal proportional to the amplifier (100) output signal envelope. A multiplier (103) multiplies the amplifier output by the first means output. A second means connects the multiplier (103) output to the amplifier (100) second input. The first means is typically an absolute value detector in series with a peak value detector, which behaves as a filter.

Description

Speech signal transmission system The invention relates to a Speech signal transmission system and in particular to such a system, the one Compander possesses much improved performance.

In commonly known speech transmission systems, the speech signal compressed by a dynamic press on the transmitter side and the received signal on the receiver side to the original speech signal through a dynamic expander stretched and thus a possible noise introduced into the transmission medium decreased. In such a system, the dynamics presser and stretcher are complementary to each other; generally they are collectively referred to as companders. Typical Compander characteristics are in the CCITT recommendation G162 (The International Telegraph and Telephone Consultive Committee).

A known dynamic press (or stretcher) essentially consists from a controllable damping circuit, the transformer and diodes and an amplifier contains. The adjustable attenuator controls the AC impedance the diode by means of a current that is proportional to the envelope of the output signal from the presser (or the input signal to the stretcher), and the output of the controllable Attenuator is amplified by the amplifier.

Such a press (or stretcher) creates manufacturing difficulties to the effect that a diode circuit must be realized which has a wide Range of signal level works with high linearity. The diodes must with regard to their characteristic should be uniform or match and the presser must with regard to its diode characteristic must be precisely adapted to the stretcher. This has to be done made, especially carefully when selecting the diodes for the presser and stretcher proceed. Furthermore, since the controllable attenuator controls the presser (or the stretch>) output controls, it follows that the wider the compression (or expansion) dynamic range the greater the gain of the amplifier must be.

It is therefore an object of the present invention to provide a speech signal transmission system to provide a compander with a simple circuit structure, the determinable with regard to its operating characteristics and easy to manufacture is.

This object is achieved in the speech signal transmission system according to the invention with regard to the dynamic presser by the features in the characterizing part of the claim 1 or by the claim '2 and with regard to the dynamic stretcher by the Features in the characterizing part of claim 3 solved.

In such a system, a compression / expansion ratio of 2 can theoretically be achieved and it is therefore the necessity of element selection and adaptation to achieve such a compression / elongation ratio is reduced. Since the system does not use loss or attenuation switching for a dynamic range, is In addition, the effectiveness of the transmission is greatly improved.

Furthermore, the input level changes over a wide range maintain good linearity of the compander output.

Further details and embodiments of the invention are shown in the following Refer to the description in which the invention is based on the illustrated in the drawing Embodiments are described and 'explained in more detail together with the prior art will. 1 shows a block diagram as an example of a speech signal transmission system, FIG. 2 is a circuit diagram of a known presser, FIG. 3 is a circuit diagram of a known one Dehners, FIG. 4 is a block diagram of a presser according to an embodiment of the present invention, FIG. 5 is a block diagram of a presser according to another Embodiment of the present invention and FIG. 6 is a block diagram of a Dehners according to the present invention.

1 is a block diagram of a speech signal transmission system shown, which has a compander (dynamics presser and stretcher) to reduce of interfering noises in the transmission medium. The voice signal is on the sender side pressed together by means of a dynamic presser 1 and from a transmitter 2 via a Transmission medium 3 transmitted. The transmitted signal is on the receiving end received by an I.mpfAnger 4 and to the original speech signal by means of a Dynamic expander 5 pulled apart or stretched. Figs. 2 and 3 show circuits of a well-known dynamic press or

an extender that is used in this system. According to Fig. 2 tst a speech input signal is applied to terminals 21 and 21 'and the terminals 26 and 26 'supplied via a press group, of resistors 11 to 14, diodes 15 and 16, a transformer resp.

Transformer 10, an amplifier 17 and a transformer or

Includes transformer 18. The output signals 24 and 24 ', which from a part of the transformer 18 are removed, are rectified and by means of a control circuit 19 filtered or screened.

The resulting control signal 25 becomes a connection point fed back between the diodes 15 and 16 of the press circuit.

When the input signal is high, the diodes will 15 and 16 brought into the conductive state by the control signal 25. In contrast the two diodes are brought into the non-conductive state when the input signal is at a low level. In other words, the adjustable attenuator (Variolosser), which contains the press circuit and the control circuit 19, works in such a way that the loss increases when the input signal reaches a given value, i.e. a unchanged level, and that the loss decreases as the input signal falls below an unchanged level. This adjustable attenuator changes the levels of the input signals 22 and 22 'of the amplifier 17, whereby the changed Part of the input signal level is squeezed into output signals 26 and 26 '. A dynamic press of this type has manufacturing difficulties in that Diodes 15 and 16 can be realized with the desired linearity over a wide range Range of the input signal, i.e. via an input signal level change of 50 dB (or via a dynamic presser output level change of 25 dB). Further the diodes used in the dynamic press must be uniform in terms of their characteristic curve match and be carefully chosen to be a Have a characteristic that is adapted to the dynamic stretcher or what suits him entails an intricate process for making the dynamic presser. Of the known dynamic press is therefore not applicable in practice than ever The wider the dynamic compression range, the greater the gain factor of the amplifier.

Fig. 3 shows the circuit of a known dynamic stretcher which is used for Pulling apart or stretching the compressed or

compressed signal is used. According to FIG. 3, the compressed Speech signal applied to terminals 41 and 41 'and in two by means of a transformer or transformer 30 divided; part of it leads to a dynamic strainer circle, of diodes 34, 35, resistors 31, 32, 33, 39 and 40, and the other part to a control circuit 36 which rectifies and filters or sieves the input signal thus generating a signal proportional to the envelope of the input signal is. The expansion circuit, which is created via the diodes 34 and 35 through the resistors 31, 32 and 33 is completed, is operated so that the forward resistance of the diodes 34 and 35 is changed by a control signal 44 from the control circuit 36, whereby the Termination condition of the transformer 30 is changed. This Dehnerkreis and the Control circuit 36 form a circuit of an ironable attenuator (i.e. Variolossers), which is operated so that the loss decreases as the input signal increases as an unchanged level, and that the loss increases as the input signal becomes smaller than an unchanged level. If thus the adjustable attenuator and the amplifier 37 are operated in combination, that appears stretched speech signal between output terminals 45 and 45 '. This dynamic stretcher is impractical or in not applicable in practice.

In contrast, the dynamic presser and the dyhamic stretcher work accordingly of the present invention, shown in FIGS. 4 to 6, without the disadvantages of the known circuits.

The principle of the dynamic presser is described with reference to FIG.

The dynamic presser has an input terminal 104, an output terminal 105, a differential amplifier 100, an absolute value detector (or rectifier 101), a peak detector circuit or circuit (or filter 102) and a multiplier or multiplier 103. The test value detector 101, the peak detector circuit 102 and the multiplier 103 form a circle or Circuit 106, which is similar to a dynamic expander shown in FIG.

When, generally speaking, two inputs Vx and Vy to the multiplier are applied, the resulting output pal Vo can be expressed as follows become: Vo = k1.Vx.Vy .... (1), where k1 is a proportional constant.

According to the invention, an input signal F (t) is sent to terminal 104 of the Differential amplifier 100 applied. The output signal G (t) of the differential amplifier 100 is divided or branched into three parts: The first part is the one The input of the multiplier 103 is supplied, the second part of the output terminal 105 and the third part to the absolute value detector 101 and from there to the peak value detector circuit 102. The output of the peak value detector circuit 102 is a voltage E corresponding to the Level proportional to r, which corresponds to the envelope of the output signal G (t). The signal E is fed to the other input of the multiplier 103. This tension E is proportional to the input level of the peak detector circuit 102 and therefore proportional to the level g of the output signal G (t), i.e. the input level of the absolute value detector 101. Therefore: E = g .... (2) where k2 is a proportional constant.

The level h of the output signal H (t) of the multiplier 103 becomes off Equation (1) determines: h = k3E-g .... (3) where k3 is a proportional constant is.

Equations (2) and (3) result in h = k4 * g2 .... (4) where k4 = k2.k3 is a proportional constant.

4, the two input signals are the differential amplifier 100 F (t) and H (t), of which the signal H (t) is the feedback signal G (t). The gain factor p of the feedback loop is given by / 3 = h / g .... (5) Equations (4) and (5) result in p k4 g .... (6) The output level g of the differential amplifier 100 under the feedback condition is expressed by g = Go (f-Rg) .... (7) where Go is the gain of the differential amplifier 100 is when the feedback loop is open and where f is the level of the input signal F (t) is.

Equations (6) and (7) give: g = Go (f-k4 g2) .... (8) If the open gain factor Go is sufficiently larger than 1, then: or g = k5.fl / 2 .... (11), where k5 is a proportional constant.

For the sake of simplicity, assume kr = 1. Then there is proportion of the input level to the output level 20 log f. 20., 10g g in dB = 2. With anaeren worren, the DynamlKpresser nar a compression DZW. stress ratio of 2, as it is determined in the CCITT recommendation G162.

The differential amplifier 100 can be constructed in a simple manner, for example from an operational amplifier juPC151A manufactured by the applicant and resistances. The absolute value detector 101 can, for example, consist of a simple, known full-wave rectifier with transformers and diodes formed xin. The peak detector circuit 102 can for example be formed from a simple, known circuit, the capacitors and resistors are assigned to each other in parallel. The multiplier 103 can be a common multiplier, for example one which has the type shown in Fig.

16 of Motorola's Linear Integrated published in December 1971 Circuits Data Book "used circuit MC 1594L (MC 1494L). By appropriate Selection of the values of RX, RY, RT and RL of the "Motorola" circuit and the resistance of the differential amplifier 100 can be the constant k5 of the equation (11) can be determined arbitrarily. Instead of the absolute value detector 101 and the peak value detector circuit 102, any circuit capable of generating a signal that the envelope of the output signal 105 is proportional.

In general, depending on the application, the multiplier can be used as a divider circuit. For example, the multiplier 103 can be used for the purpose of the dynamic presser according to the present invention. In detail, in the case of a divider circle, the relationship between two input signals J1 (t) and J2 (t) and an output signal Jo (t) expressed by Jl (t) Jo (t) = ( ) t .... (12).

J2 (t) In Fig. 5, it is assumed that the output signal Jo ('t) is on the terminal 122 to the input terminal 123 of the divider circuit or circuit 120 by means of of the absolute value detector 101 and the peak value detector circuit 102 are fed back will. Then equation (12) yields Jo (t) IJo (t) I = k6ZJ1 (t) .... (13) where k6 is a proportional constant.

Equation (13) expresses or has the same meaning as Equation (11). Equation (13) therefore indicates the fact that the dividing circle 120 can be operated as a dynamic press according to the invention, which is a compression or. A compression ratio of 2 brings.

The divider cres can, for example, from one in FIG. 16 of the December 1971 published "Motorola" s Linear Integrated Circuits Data Book "shown Circuit be formed.

Fig. 6 shows a block diagram of a dynamic stretcher according to the invention, which is similar to circuit 106 shown in FIG. The output level h des Dynamic stretcher at the terminal 201 is expressed by equation (4). That's why is the ratio of the output level to the input level 20 log g in dB equals 2. (For the sake of simplicity it is assumed that the constant k4 is equal to 1).

According to the invention, as described above, a compression / expansion ratio of 2 theoretically easily realized, with the result that the need the selection and adaptation of elements to achieve such a compression / expansion ratio is decreased. Furthermore, the system according to the invention makes the use of a loss or damping circuit for a dynamic range superfluous, so that the effectiveness or effectiveness of the transmission can be improved. Furthermore, a wide range of input level changes, a good linearity of the compander output maintain.

Expectations:

Claims (3)

Claims 9 speech signal transmission system with a dynamic presser on the transmitter side and a dynamic stretcher on the receiver side, thereby characterized in that the dynamic presser (1) has a differential amplifier (100) the first input terminal (104) of which an input signal is applied, a first means (101, 102) which is one of the envelopes of the output signal from the differential amplifier (100) can generate proportional signal, a multiplier (103) that the output of the differential amplifier (100) through the output of the first means and second means for connecting the output terminal of the multiplier (103) to a second input terminal of the differential amplifier (100). 2. Speech signal transmission system with a dynamic press on the Transmitter side and a dynamic expander on the receiver side, characterized in that that the dynamic presser (1) 'has a divider circuit (120) at its first input terminal (121) an input signal is applied, a first means (101, 102) which is a the Envelope of the output signal of the divider circuit (120) proportional signal and second means (123) for connecting the output terminal of the first means (101, 102) to a second terminal of the divider circuit (120). 3. Speech signal transmission system, in particular according to claim 1 or 2, characterized in that the dynamic stretcher (5) has a means (101, 102) which can generate a signal proportional to the envelope of the input signal, and a multiplier (103) which converts this input signal to the output signal from the signal generating means (101, 102) can multiply. Blank page