DE2709817C3 - Circuit arrangement for a loudspeaker station - Google Patents

Description

balanced and for a change of operating position (change of speech direction) or for its preparation be evaluated.

An embodiment of the invention will be explained with reference to a figure, ϊ

The figure shows a station circuit with the connection points a and b, with a microphone M, a listener T, a loudspeaker L, a rectifier bridge GB, an output transformer ÜA _r a fork transformer ÜG, a transmission amplifier SV, a ι ii input amplifier EV, a control amplifier STV , a sketched push-pull output stage GE, a likewise sketched supply voltage regulator SR, furthermore with the field effect transistors FTl, FT2 and FTZ as control elements, with the simulation N, the resistors ι ■ -> the R 1 to R 15, the capacitors Cl to CIl and the Rectifier diodes G1 to G 7.

In the following the function of the circuit is explained with reference to FIG It is assumed that at the connecting points a and b of a sound telephone station performing circuit arrangement, a DC supply voltage _V via eir-; Connection line VL is present (e.g. positive potential at a and negative potential at b). Furthermore, a voice signal voltage (alternating voltage) should be applied to the connection points a and b of the circuit arrangement r> arriving via the connecting line VL. First of all, the course of the supply voltage (direct voltage) applied via the connecting line VL is considered.If the positive potential is assigned to the connection point a , this is then transferred via a winding of the output transformer UA (parallel to this also via the simulation NX part of a winding of the fork transformer ÜG and the rectifier bridge GB each to the one supply voltage input of the amplifier EV (receiving amplifier), SV (transmitting amplifier) and STV (control amplifier), as well as to a supply voltage input of the indicated push-pull output stage GE.

At the same time, this potential is applied to the microphone M, the loudspeaker L and to one of the supply voltage inputs of the field effect transistors FT1, FT2 and FTZ, which represent the control elements.

The negative potential of the supply voltage lying at the connection point b of the circuit arrangement in the present example reaches the corresponding supply voltage inputs of the amplifiers EV, SV and 5TV via the rectifier bridge GB and also to the corresponding input of the push-pull output stage GE

If a voice signal voltage is applied to mn via the connecting line VL (receiving position), this is transmitted via the rectifier bridge GB (via the two rectifiers that are operated in the direction of flow) first via the fork transmitter ÜG to the receiver T. The two diodes D arranged in the receiver circuit \ and D 2 serve as hearing protection. Furthermore, the speech signal spaiinung reaches the mi control input c of the receiving amplifier EV via the resistor RZ and the capacitor Cl, which emits a corresponding amplified signal at its signal output e for further amplification by the push-pull output stage GE . The capacitor Cl and the resistors R 4 and R 14 determine via the t> s control inputs c and d of the receiving amplifier EV its operating point and degree of negative feedback. In addition, the DC voltage-related operating point of the control input c of the amplifier EV is determined with the aid of a voltage divider formed from the resistors R 1 and R 2.

The amplified speech signal emitted by the push-pull output stage GE is fed directly to a connection point of the loudspeaker L, which, in the present case, has its other connection point at the positive potential of the supply voltage

The voice signal voltage fed to the loudspeaker L is also applied to the capacitor CZ via the resistor R 5, with the aid of the ratio of the resistors R 5 and R 6 a voltage division and a voltage via the capacitor CZ with the aid of the rectifiers GZ and G4 on the capacitor CIl is built up (which can be reduced again via the resistor Λ12). The same voltage is also constructed through the diode G 7 on the capacitor C4, where a discharge resistor R is connected in parallel order is with the help of the diodes GZ and G 4 and G 5 and GS won * control voltage to the corresponding three Steoerelektroden the controls FTL , FT2 and FTZ (field effect transistors).

As can be seen from the above, this control voltage present at the control electrodes, represented by the voltage at the capacitors CU and C4, corresponds to the value of the voice signal voltage present at the loudspeaker L and thus the voice signal voltage output by the push-pull output stage GE. The greater this control voltage, the more the field effect transistors FT1, FT2 and FTZ are controlled through.The field effect transistors FT2 and FTZ thus become a derivation path for the voice signal voltage fed to the receiver amplifier EV , which is controlled according to the size of the voice signal at the loudspeaker L , whereby its output signal at the signal output e is influenced accordingly. This purge path runs through the capacitor C7, resistor R9 and, based on the control FT2, via the resistor R 13 Thus, the gain of the receiver amplifier EV is more or less weakened and it will be the incoming regardless of the size of the connecting line VL Speech signal result in the specific desired volume on the loudspeaker L which is below the overdrive limit. Since the control element FT2 is preceded by an additional resistor R 13 in the derivation path of the receiving amplifier, which has a relatively high resistance value compared to the resistance R 9 common to the two control elements FT2 and FT3 and since the control element FT3 is not preceded by a further resistor corresponding to the resistor R 13, this control element has a much greater effect on the control input c of the receiving amplifier EV. This results in a sufficiently large regulating range for the control of the receiving amplifier £ Vin for setting an average amplification of the voice signal voltage corresponding to the connected connection line VL as a function of the voice signals present at the loudspeaker L.

The control voltage that forms on the capacitors CIl and C4 and is applied to the control electrodes of the control elements FT2 and F ^ .I is also applied to the control electrode of the control element FTl and controls this also more or less permeable depending on the size of the speech

Signal voltages at the loudspeaker L, and the negative feedback of the amplifier SV via the resistor R 15 to the alternating current parallel connection of the resistors FT1, 10 and Λ 11 in connection with the capacitor CB changes the transmission gain. This has the effect that the transmission amplifier SV amplifies the more the higher the AC voltage at the push-pull output stage GE and thus the control voltage at the electrode of the field effect transistor FT 1, that is, by means of the negative feedback of the transmission amplifier SV , one more occurs in the receiving position or less strong switchover to the transmission position corresponding to the control voltage and thus a later switchover to the full transmission position is facilitated.

If the microphone M is being discussed during transmission, the voice signal voltage is fed to the transmitter amplifier SV via the capacitor C6 to the amplifier input f. The voice signal reaches the output transformer ClA via the signal output h of the transmitter amplifier SV and thus also to the connecting line VL Die from the asymmetrical connected microphone M are emitted speech signals at the same time via the capacitor C9 at the control input / a control amplifier STV. At the output / of the control amplifier STV , a corresponding, amplified voice signal voltage is output via the capacitor CS , from which a DC voltage is obtained with the help of the rectifiers GS and G 6, which is derived from a portion of the voice signal voltage on the capacitor C 4 that may already be present on the capacitor C 4 Loudspeaker L generated potential and thus the control voltage at the control electrodes of the field effect transistors FT1 and FT2 is connected in parallel. As a result, the gain of the transmit amplifier SV via its control input £ is possibly increased even further, while the gain of the receive amplifier EV via its control input c and via the components R 13, Ci and R9 is reduced. This means an accelerator. Necessary full switchover of the station switching to the transmission position and thus an attenuation of the receive channel and a de-attenuation of the transmission channel.

Since the capacitor CIl compared to that by the rectifiers GS and G 6 for the capacitor CA

κι generated charging voltage is blocked by the rectifier Gl , the AC voltage at the control amplifier 57 "V at its output / output will not affect the capacitor CIl. This means that the through the incoming (during the

ii Reception position) the speech signal voltage applied to the loudspeaker L , the control voltage obtained for the control element FT3 is not influenced by the control voltage of the control amplifier and thus no excessive reduction in the reception amplifier

: n can be done. Only in a smaller area is there a change in the receive and transmit gain by FTX and FT2, depending on the operating position to be set, as a function of the control voltage on the capacitor C4.

:> From the above it follows that it is with help the circuit arrangement according to the invention is possible in a simple manner, a circuit arrangement for to create a loudspeaker station controlled depending on the voice channels, which is responsible for the changeover

! "tion of the speech direction a relatively small control stroke has, so that a feedback whistle is avoided, however, at the same time as setting the middle Reception gain, based on the attenuation of the current connection, is a relatively large one

Γι has control range.

1 sheet of drawings

Claims (2)

Claim: Circuit arrangement for a loudspeaker station with kanalindiyidueljen transmit or receive amplifiers, the control of the gain and the switching from one operating position to the other (e.g. from receiving mode to transmitting mode) depending on the size of the voice channel (receiving channel or Transmission channel) and the control voltages required to control the amplification and the operating position switchover are obtained from a portion of the speech signal voltage applied to the loudspeaker and / or from a portion of the microphone voltage, and a first one for the receiver amplifier and a second one for the receiver amplifier, which expands these control voltages Transmitting amplifiers provided with a first or second additional control voltage obtained from the evaluation result controlling the respective amplifier with an extremely low power loss are arranged, characterized in that a voltage-controlled third control element (AGV) is provided, the speech signal output (m) through a resistor (R 9) with the voice signal input (c) of the receiving amplifier (F. V) is connected, this ohmic resistor (R 9) having a much smaller resistance value than the ohmic resistor (R9 + R 13) which defines the range of the first additional control voltage and via which the speech signal output of the most control element (FT2) has an extremely low value: Power loss is connected to the speech signal input (c) of the Ijnpfangsträger (EV) and that furthermore the control input of the third control element (FTS) , which is affected by the control voltage obtained from a portion of the speech signal voltage applied to the loudspeaker (L ), compared to the control input of the, which has the same control voltage first control element (FT2) and the second control element (FTi) is decoupled with the aid of a decoupling element (Gl) with respect to the control voltage obtained from the microphone voltage. The invention relates to a circuit arrangement for a loudspeaker station with channel-specific transmission or receiving amplifiers, with the control of the amplification and the switching from an operating position (e.g. reception position) to the other operating position (e.g. transmission mode) depending on the size of the the voice signal voltages located in the respective voice channel (receiving channel or transmitting channel) takes place and wherein the control voltages required to control the gain and the operating position switching from a portion of the voice signal voltage applied to the loudspeaker and / or from a Proportion of the microphone voltage can be obtained and a first evaluating these control voltages for the receiving amplifier and a second one for the transmitting amplifier with one of the The first or second additional control voltage obtained from the evaluation result controls the respective amplifier, with an extremely low power loss control element are arranged. It has already been proposed such a circuit arrangement are provided in both transmit ~> in the voice channel speech signal amplifiers, which the speech level located on the voice channels in the aforementioned manner with the help of obtained through appropriate controls additional stresses in dependence or voice K) signal voltages are controlled. The control of Receiving and transmitting amplifiers take place in roughly the same size control ranges (control stroke as small as possible in order to avoid whistling precisely), which in the case of high incoming speech levels the distortion-free limitation of the signal level at the loudspeaker is no longer ensured Furthermore, a circuit arrangement for automatic gain control is known (DE-OS 21 37 127), but where the regulation always refers to one 2'i is related to a fixed level, while, according to the invention, a speech level-dependent gain control is to take place in order to achieve switching into a different speech direction.
A circuit arrangement for automatic 2) see voice controlled gain control known (DE-OS 1812 273), in which the output power of the respective voice channel amplifier after exceeding a certain limit is reduced. However, this does not allow gain control of ! (> Receive and transmit channel levels are dependent on each other. The invention is therefore based on the object of a To create circuitry for a voice level controlled loudspeaker station that has a relatively r> should have a small control stroke, so that a feedback whistling is just safely avoided, which, however, is relatively large for setting the average automatically regulated reception volume when adapting to the connection line connected in each case 4 (i has control range. This is achieved according to the subject matter of the invention in that a voltage-controlled third Control element is provided, the speech signal output via an ohmic resistor with the 4S voice signal input of the receiving amplifier connected is, this ohmic resistance has a much smaller resistance than the the area of the first additional control voltage defining the ohmic resistance over which the speech signal output iii gear of the first control element with extremely low Power loss is connected to the speech signal input of the receiving amplifier and that continues the one obtained from a portion of the speech signal voltage applied to the loudspeaker Vi control voltage afflicted control input of the third control element with respect to the control input of the first control element and the second control element afflicted with the same control voltage with the aid of a decoupling element with respect to the M> the control voltage obtained from the microphone voltage is decoupled. This results in the advantage that when there is a difference over the receiving channel high voice signal voltages, these voice signal voltages initially basically all in one b ^r > large control range are amplified or attenuated to a certain desired size and that level fluctuations during the existence of the connection within a relatively small control range