DE2024129A1 - Arrangement to compensate for the different attenuation behavior of telecommunication lines - Google Patents

Description

Arrangement to compensate for the different damping behavior of communication lines The invention relates to an arrangement that has the different To compensate for the attenuation behavior of telecommunication lines, especially telephone lines is able to.

Telephone lines have different attenuation behavior compared to the speaking frequencies. If the attenuation is very high, the Speech exchange voltages are highly amplified. If, on the other hand, the attenuation is low, the gain must not be too high, otherwise neighboring lines will be disturbed become (crosstalk). In general, a level of 0 Np, corresponding to 775 mV, must not be exceeded. Amplifiers that are only relevant for one line are, can still be in their transmission factor (gain factor) the properties adapt to this line. It is different, however, when different lines with be connected to an amplifier, so the amplifier can be selected to a certain extent. This case occurs, for example, with the so-called.

Call forwarding in front of the forwarding of calls that are for intended for one subscriber, is used for another subscriber, for example for forwarding of calls to a branch that is not manned in the evening to the main office.

The relay station receives depending on the quality of the telephone connection with the caller extremely different attenuated speech tensions, so that it cannot be equipped with one of the usual amplifiers.

The aim of the invention is to solve this problem of modern telephone technology by means of an arrangement which largely compensates for the different attenuation behavior of the telephone lines. This aim is achieved in that an amplifier is provided which, by means of non-linear elements, provides a transmission behavior according to the following equation: where v is the gain, UE is the input voltage, UA is the output voltage, a is the compensation factor and c is a constant that can be determined from the absolute values of UE max and UA max or UE min and UA tln.

An amplifier with this transmission behavior delivers an output voltage UA, which according to the relationship 1 UA = c. UE a depends on the input voltage UE. Relative fluctuations in the input voltage UE therefore lead to relative fluctuations in the output voltage UA reduced by the compensation factor a. In this mode of operation, the arrangement of the invention corresponds to a dynamic compressor. One difference, however, is that it is less the dynamics of the alternating voltages generated by speech, but rather the "dynamics" in the damping behavior of different telephone lines that are compressed. Another difference is that the amplifier according to the invention treats small and large AC voltages equally with regard to distortion (distortion factor), since the compensation factor a is always constant and the differential quotient of the output voltage is always the differential quotient of the input voltage according to the relationship is proportional.

As a result of its compensatory behavior, said amplifier amplifies small input voltages to a greater extent than high input voltages. So that interference voltages in pauses in conversation, when there is no alternating speech voltage, not with the highest A further training sees the gain factor amplified and thus audible as noise the invention provides that an input AC voltage is fed to the amplifier, that from the speech alternating voltage and an additional alternating voltage by superposition or modulation is composed.

The additional alternating voltage holds here when the alternating speech voltage ceases the gain factor to a value that corresponds to its level. You can for it provide their own generator; on the other hand, in telephone systems are multiple Pilot tones are required to switch the transmission direction, with the switch command can be given by briefly interrupting a continuously applied pilot tone can, under these conditions is an advantageous embodiment of the invention characterized in that the additional alternating voltage is used to switch the transmission direction pilot tone of constant height and frequency used by the amplifier.

In the case of transmission systems for higher frequencies, the additional oscillating voltage have a frequency outside of the audible range. Then she doesn't kick at all in appearance. In the case of telephone lines, however, a frequency must be selected for this dierpoh lies within the transmission band and thus in the audible range. So that they cannot be heard as a continuous tone during pauses in conversation, see a further training of the The invention provides that the output voltage of the amplifier is fed to a filter, that keeps the additional AC voltage away from the receiver.

The arrangement of the invention can in itself be used anywhere where tensions of unknown levels are to be intensified. It has particular advantages but where there are high voltage fluctuations due to different attenuation is to be expected. A special embodiment of the invention is therefore aimed at that they are within half a telephone transmission system between two telecommunication connections is used.

The advantages achieved with the invention are in particular: that a call forwarding is made possible, although the -forwarding Calls on different lines arrive with different attenuation, and that less attenuated alternating speech voltages are not more distorted than strongly attenuated alternating speech voltages. Furthermore, simple additional measures possibly using means already available for other purposes (pilot tone) effective noise reduction achieved.

The following is an embodiment of the invention, which is in the Drawing is shown, described in more detail.

1 shows a basic circuit diagram for call forwarding with one used between two telephone connections to compensate for the attenuation Amplifier, FIGS. 2 and 3, characteristic curves of the amplifier at different levels of the additional alternating voltage and with different line attenuation.

Fig. 1 makes the problem of a call forwarding clear, A subscriber station at location B is not always busy, but calls from anyone Accept participants at location C and to a permanently manned location at the location Forward A. The participant in C should hear the participant in A as if he were would be in B, and likewise the participant in A should hear the participant in C so, as if it were in B. Between locations A and B and 3 and C are located Telephone lines 3 and 5 of unknown and dependent on the connection establishment, respectively different attenuation, shown is only the case that the participant is in A speaks and the participant in C receives. By switching the traffic direction It is also possible to speak from C and receive in A.

In any case, only two-way communication takes place, since the connection is Uber two lines goes and because of the amplifier in both lines no two-way connection is permitted (risk of vibration). To switch the Traffic direction is a pilot tone generator 2 in A.

At location B an amplifier 4 is provided1 whose transmission dimension v = WUEA according to - 1) v = c. UE a the relationship: depends on the input voltage. Here, a is the compensation factor and given by: log UE max I log UE min log UA max - log UA min and c a constant adapted to the absolute level of the voltage limit values UE max and UA max or UE min and A min. In the example it is assumed that the level on line 3 is at least -6 Np (1.92 mV) and at most -1 Np (285 mV). The amplifier 4 should compensate for the voltage differences in the ratio 1: 148 to such an extent that only voltage fluctuations in the ratio 1: 4.5 occur, the maximum level of the output voltage being 1 Np (285 mV). This results in a value of -2.5 Np (63.5 mV) for the minimum level of the output voltage and a value of 3.33 for the compensation factor a; 1 is therefore 0.3, from the a requirement that for UE = 285 mV should also be 285 mV, c results in e0.8788, i.e. about 0.415.

A characteristic curve according to curve a in corresponds to the values determined Fig. 2.

If the microphone 1 in FIG. 1 is discussed normally, it supplies voltages UM of about 285 mV. With an ideal transmission path 3 (attenuation zero) is the input voltage UE of the amplifier 4 is also 285 mV, and it gives an output voltage UA from 285 mV. With 1 Np attenuation on line 3, the voltage UE is only 105 mV, but the output voltage UA is still 213 mV. Set 2 Np line attenuation the receive voltage in 3, i.e. UE, down to 38.7 mV. At the output of the amplifier 4 a voltage UA of about 155 mV now appears. The amplifier 4 is therefore the same different attenuations of the line 3 largely. The relative change dUA corresponds to the output voltage - UA corresponds to 0.3 times one at every point on the curve relative change nr of the input voltage. Hence the total harmonic distortion is the output voltage independent of the level of the input voltage and thus of the attenuation of line 3.

The participant in C therefore actually hears the participant in A as follows: as if it were in B, At location A there is an alternating voltage generator 2 is provided, which generates a pilot tone Up of 2.7 kHz. This pilot tone is always on and is only used for a short time to switch the direction of the call using a button or the like interrupted. A filter 6 keeps him away from the listener 7 of the subscriber in C. The said In the subject matter of the invention, pilot tone is used in addition to noise suppression exploited. Because of its compensatory behavior, the amplifier favors 4 small voltages versus high voltages and thereby reduces the signal-to-noise ratio. If it is 5 Np on the input side, this drops to 1.5 Np on the output side. Interference voltages of -6 Np (1.92 mV) generate, for example, if there is no alternating speech voltage is present, according to curve a, output voltages of -2.5 Np (63.5 mV). You could take breaks in conversation can be heard as noise. With a pilot tone that superimposes the microphone voltage and the amplifier input is applied during the pauses in speaking, is this disadvantage is overcome. Curve b in Fig. 2 shows the effect of a pilot tone the voltage Up of -3.5 Np (23.3 mV) on the transmission behavior of the amplifier 4 compared to a non-attenuated microphone voltage UM. To the normal alternating speech voltage of 285 mV, the pilot voltage Up of 23.3 mV has no significant influence. she therefore again leads to an output voltage of 285 mV. Lies in a pause in speaking If no voltage UM is applied, but an interference voltage of 1.92 mV, this becomes the pilot voltage Up of 23.3 mV superimposed. The amplifier 4 amplifies them only in that for one Input voltage of 23.3 mV valid level, in the present case to an output voltage of about 11 mV (the output voltage of about 133 mV is later eliminated by the filter 6 and therefore does not need to be taken into account instead of a signal-to-noise ratio of 1.5 Np (without pilot tone) is now consequently a S / N ratio of about 3.25 Np (285: 11 = 25.9) was obtained.

Curve c in Fig. 2 gives the corresponding ratios for a pilot voltage Up by -2 Np (105 mV) again, as with curve b it is assumed that the line 3 has zero attenuation. A microphone voltage UM of 285 mV now results in an output voltage UA of 270 mV, an interference voltage of 1.92 mV is only achieved with the one valid for 105 mV Gain factor increased from around 2 to around 3.9 mV. The output-side signal-to-noise ratio is consequently about 4.25 Np (270: 3.9 = 69).

Since the generator for the pilot voltage Up is in the same place with the Microphone 1 is arranged, the voltage Up through the line 3 is to the same extent attenuated like the voltage UM. Their effectiveness in terms of noise reduction is therefore independent of the attenuation of line 3. In Fig. 3 it is shown how the amplifier 4 behaves with a line attenuation of 2 Np, namely Curve a applies again for the case without a pilot tone, curve b for a pilot voltage of -3.5 Np and curve c for a pilot voltage of -2 Np.

A microphone voltage of 285 mV (-1 Np) is achieved by the line attenuation of 2 Np by a factor of 7.389 and leads to an input voltage UE of 38.6 mV (-3 Np), this corresponds to an output voltage UA of 157 mV (curve a). However, since the pilot voltage Up is attenuated by the same factor, now is in the speaking pauses with a pilot voltage of 23.3 mV (-3.5 Np) at location A at location B a voltage of 3.15 mV (-5.5 Np) at the amplifier input (curve b). You superimposed any interference voltage that may occur due to crosstalk or the like, for example again by 5 Np (input-side signal-to-noise ratio) below the alternating speech voltage from now -3 Np is -8 Np, i.e. 0.26-mV. This interference voltage is increased by the amplification factor relevant for UE = 3.15 mV from 23.8 to 6.19 mV reinforced. The signal-to-noise ratio on the output side is thus around 3.24 Np (157: 6.19 = 25.4). It is therefore just as large as in the example in FIG. 2, where the damping on line 3 was considered negligibly small (O Np).

In curve c are the ratios for a pilot voltage of 105 mV (-2 Np) given at location A. At location B, attenuated by 2 Np, it results in one in the speaking pauses effective voltage of 14.2 mV (-4 Np) and thus defines the gain factor of the Amplifier 4 in the idle state-fixed at 8.2. An interference voltage of 0.26 mV (-8 Np) thus leads to an output voltage of 2.13 mV, while the speech alternating voltage of -3 Np results in an output voltage of 150 mV. The output-side signal-to-noise ratio is therefore 4.25 Np (150: 2.13 = 70) and agrees with the above with reference to Fig. 2 with an attenuation of 0 Np on line 3.

As the calculation examples make clear, the amplifier 4 with the specified characteristic curve provides extensive attenuation compensation and through the Additional voltage for which a pilot tone that may already be used is used can be achieved, a noise suppression independent of the line attenuation.

Claims (4)

Expectations Arrangement for compensating for the different attenuation behavior of telecommunication lines, characterized in that an amplifier (4) is provided which, by means of non-linear elements, generates a transmission behavior according to the following equation: where v is the gain, UE is the input voltage, UA is the output voltage, a is the compensation factor and c is a constant that can be determined from the absolute values of UE max and UA max or UE min and UA min. 2. Arrangement according to claim 1, characterized in that the amplifier (4) an input alternating voltage (UE) is supplied, which is derived from the speech alternating voltage (UM) and an additional alternating voltage (Up) composed by superimposition or modulation is. 3. Arrangement according to claim 2, characterized in that the additional alternating voltage (Up) a used to switch the transmission direction of the amplifier (4) Pilot tone is constant altitude and frequency. 4. Arrangement according to claim 2 and claim 3, characterized in that that the output voltage (UA) of the amplifier (4) is fed to a filter (6), that keeps the additional AC voltage (Up) away from the receiver (7). 5, arrangement according to claim 1 to claim 4, characterized in that that they are within a telephone transmission system between two Ferzmeldeverbindungen (3 and 5) is inserted. L e r s e i t e