DE2411501A1 - CONNECTOR FOR AN ELECTROACOUSTIC COMMUNICATION SYSTEM AND METHOD OF CONTROLLING SUCH A DEVICE - Google Patents

Description

PATENT LAWYERS

MANITZ, FINSTERWALD & GRÄMKOW

March 11, 1974-N2000

NORTHEEN "EIiEOTEIO OQMEAHI LIMITED 1600 Dorchester Boulevard Vest Montreal, Que ,, Canada

Connection device for an electroacoustic communication system and methods of controlling such a device.

The invention relates to a connection device for an electroacoustic Communication system that uses loudspeakers and microphones, for example, and is set to transmit or operate. Reception mode can be changed.

In the conventional arrangements, a terminal device for an electroacoustic communication system includes a transmission channel with a microphone to which a

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DR. G. MANITZ · D1PL.-ING. M. FINSTERWALD DIPL.-ING. W. G R A M K O W ZENTRALKASSE BAYER. FOLK BANKS MÖNCHEN 22, ROBERT-KOCH-STRASSE 1 7 STUTTGART 5O (BAD CANNSTATT) MÖNCHEN. ACCOUNT NUMBER 7270 TEL. (089) 22 42 II, TELEX OS-29672 PATMF SEELBERGSTR. 23/25. TEL. (0711) 5672 61 POST CHECK: MUNICH 77O62-8O5

is connected more strongly downstream, as well as a receiving channel with an amplifier, which is followed by a loudspeaker is. During transmission, the microphone picks up acoustic signals from its surroundings. These signals are amplified and coupled to a suitable transmission device, e.g. a telephone line, where the connection i; i is a typical application takes place via a hybrid circuit. During reception, the signals from the transmission device are transmitted via the hybrid circuit coupled to the receiving channel and passed on in the form of acoustic signals.

The receiving operation should proceed in such a way that it is possible to limit or control the amount of signaling energy that is coupled to the transmission device, so that a person who receives the signals from the transmission device can record them with sufficient volume. in order to be able to understand them, but that on the other hand these signals are not of such a loudness that physical discomfort and / or impermissible signal distortion are generated. One solution to this problem would be to introduce a manually adjustable volume control into the transmission channel. However, this results in inconvenient handling for the user of such an application, and the problem becomes even greater if the setting is incorrect. Another solution would be one or more limiting arrangements associated with the hybrid circuit or the transmission device. Conventional limiting arrangements incorrect. such as i: i suitably switched diodes (back-to-back diodes) or varistors tend to introduce distortions due to word confusion and are generally only used to reduce very loud noises such as clicks, cracks

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Tactile clicks, bangs, thuds and broadcast noises to eliminate. Another means of volume control is a compression circuit or a automatic volume control. Though using such an arrangement a very constant speech signal level can be achieved, there is a risk that speech pauses with a high background or ambient interference signal filled wcrdea. Another The disadvantage is that the normal speaking volume as well as the modulation of the voice of the user such device based on the effect of the automatic Volume control can be masked and corrupted.

It is well known that an ir. A noisy The person speaking tends to speak louder than a person who is in a relative environment quiet and quiet environment speaks. It is it has been found that there are a number of advantages in terms of gain or gain of the transmission channel with a connection device for an electroacoustic communication system in inverse relation to the acoustic noise the background or the environment is regulated «The Transmitted signals typically have a constant level of ambient noise regardless of those picked up by the microphone Ambient noise. Normally the speech level of the user of such a device changes with it the ambient noise level, although this change is not linear $ on the other hand, the Speech level tends to maintain a relatively constant level after the signals are picked up by the microphone and were reinforced. With that, those of

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a listener recorded voice signals in a typical application a preferred listening level and a natural tone or sound.

It has also been found that this type of gain control in the transmission it is particularly advantageous if it is used in voice-controlled connection devices for electroacoustic ^ Communication systems is used. In one Application, the gain factors of the respective channels can be regulated so that there are three modes of operation there, namely the transmission operation, the reception operation and an intermediate stage of these two Operating modes in which the device is not busy; this intermediate stage is to be referred to as "free operation" in the following ". If the connection device is set to free operation, this type of Gain control that by the ambient noise picked up by the microphone a substantial Bias takes place in the direction of the transmission operation. As a result, the connecting device is only then leave free mode and switch to transmission mode when it responds to signals from the microphone, which have the typical characteristics of a speech signal.

In the case of a voice-controlled device, a certain Degree of delay, the so-called hangover, when switching between reception and transmission mode strived for. It has been found that there is an improvement in the operation of a voice-controlled device results when the ambient noise detected and rectified in the device artificially increased during reception. This can largely

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prevent the device from quickly ending up Words and syllables depending on delayed acoustic signals sent from the speaker to the Microphone are transmitted, switches to transmission mode.

The present invention provides an improvement in an electroacoustic terminal device Communication system. The terminal device is to be connected to a transmission device and contains a control device to the terminal device in the two operating modes, namely transmission mode and receiving operation. The improvement includes an arrangement for generating a noise reference signal that is representative of the acoustic background noise in the environment in which the Device is operated. A government order controls them Amplification in the connection device of the communication system, if the terminal device is set to transmission mode. The controller arrangement speaks on the noise reference signal so that the gain is inversely related to the noise reference signal controlled wix "d. This is the natural tendency of a user of such a device, speaking louder in a noisy environment than in a quiet environment, balanced so that a more constant speech signal level to the transmission device is given.

The present invention further relates to a method for controlling the gain in one Connection device for an electroacoustic communication system which is connected to a transmission device should be connected. The device is characterized by the fact that it is

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drive can be operated. The foregoing has the following steps: There is a noise or Noise reference signal is generated which is representative of the background acoustic noise is in the environment in which the device is operated; furthermore, the gain is reversed Relation to the background noise reference signal regulated when the device is operating in transmission mode. Through this becomes the natural tendency of a user of such a device to be in a noisy environment speaking louder than in a quiet environment, balanced so that a more constant speech signal level is given to the transmission device.

The invention thus creates a connection device, in one embodiment an electroacoustic transducer that Has transmission and reception channels and furthermore contains a control arrangement in order to alternate in the Transmit or receive operation to work. Of the The gain factor is inversely related to the background noise in transmission mode the room regulated. This becomes the natural tendency of a user of such a device to turn into a Speaking louder in noisy surroundings, compensates for a more constant speech signal level the transmission facility is given. In a voice-controlled embodiment of an alectroacoustic Converter there is still a "free mode", in which the gain factor in the transmission channel is also regulated by the level of ambient noise in the room.

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The invention is illustrated below with the aid of exemplary embodiments explained in more detail with reference to the accompanying schematic drawings.

Show it:

Figure 1 is a block diagram of a voice-controlled connection device or electroacoustic! Converter (speakerphone) for an electro-acoustic communication system according to the invention;

FIG. 2 shows a noise circuit used in the electroacoustic transducer of FIG will;

FIG. 3 shows a circuit of a reference signal source and a noise current switch which are used in the electroacoustic Converter of Figure 1 is used;

FIG. 4 shows an additional reception transitional circuit which is included in the electroacoustic transducer of FIG is used;

Figure 5 shows a transmission transition delay circuit; used in the electroacoustic transducer of Figure 1, and

FIG. 6 shows a rectifier circuit used in the electroacoustic transducer of FIG will.

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Referring to Fig. 1, the electroacoustic transducer includes a transmission or transmission channel 10 and a reception channel 20, which by a hybrid circuit 3 with each other are connected and terminals 2 for connection to a telephone line or the like Have transmission and transmission device. The rest Part of the circuit serves as a control for the transmission and reception channels 10 and 20 via a Control signal line 55

The transmission channel 10 contains a microphone 11, which is connected to the input of an amplifier 12, the output of which is connected to the input of a transmission attenuator 13. The exit of the transmission attenuator 13 is connected to the input of the hybrid circuit 3. The receiving channel 20 contains a receiving attenuator with a Input that is connected to the output of the hybrid circuit 3. The output of the receive attenuator 21 is connected to the input of an amplifier 22. The output of amplifier 22 is to one Loudspeaker 23 connected.

The output of the amplifier 12 is also connected to the input of a microphone signal rectifier l4.The output of the microphone signal rectifier lk is to the input of an interference or noise circuit 30 and to the inverting input of a noise / signal (N / S) comparator 40 connected. The output of the transmission attenuator 13 is also connected to the input of a transmission signal rectifier 16, the output of which is connected to the inverting input of a transmission / reception (Tx / Rx) comparator 60. The output of the hybrid circuit

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is also connected to an input of a received signal rectifier 2k , the output of which is connected to the non-inverting input of the Tx / Rx comparator 60. The noise circuit 30 includes an output line for the noise current, which is connected to a noise current switch 45, and an output line for the noise voltage, which is connected to the non-inverting input of the N / S comparator 40. The output of the N / S comparator 40 is connected to an input of a reference signal source 70 via a noise / signal (N / S) line 71. The _US A g g _a31 ci _it Tx / Rx comparator 60 is connected via a transmission / reception (Tx / Rx) line 72 to an input of the reference signal source 70th The Tx / Rx line 72 is also at the input of a reception transition additional circuit 62 and the input of a transmission transition delay circuit. The output of the reception transition additional circuit 62 is connected to an input of the reception signal rectifier 24. The output of the transfer transition delay circuit 67 is connected to the non-inverting input of the N / S comparator 40.

The output of the reference signal source 70 is connected to the non-inverting input of a differential amplifier 50 via a reference signal line 74. A control output of the reference signal source 70 is connected to the control input of the noise current switch 45 via a control line 73. The output of the noise current switch is connected to the cathode of a diode 53, the anode of which is connected to the inverting input of the differential amplifier 50. A feedback resistor 5I is arranged between the output and the inverting input of the differential amplifier 50. The anode and the cathode

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of the diode 52 are connected to the output or the inverting input of the differential amplifier 50. The output: of the differential amplifier 50 is connected to the control signal line 55 with the control inputs of the transmission and reception attenuators 13 and 21.

Briefly summarized, the embodiment cited as an example has 3 different operating modes, namely transmission operation, reception operation and free operation, an intermediate stage between the reception and Forms and in which the device does not is in action. At any point in time, the ^ hasty The mode of operation is primarily determined by the signal size at the output of the transmission attenuator 13 in relation to the signal size at the output the hybrid circuit 3 occurs; in the second place will the mode of operation by the size of the transmission channel 10 received speech signal in relation to the ambient noise: fixed. Is a free enterprise provided, there is the additional advantage that the electroacoustic converter has a lower Number of switching operations is required in order to be switched to one of the two operating modes. This results in the desired high transition speed without the undesired, audible switching surges occurring. According to another feature of the present embodiment, the level of the noise becomes the Environment used to adjust and attenuate the gain of the transmission channel 10, while the electroacoustic transducer is set to either transmit mode or free mode.

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In the following, the mode of operation will be explained in detail will. The acoustic signals of the voice are picked up by the microphone 11 and through the amplifier 12 reinforced. The microphone signal rectifier provides a rectified signal that matches the signals which are picked up by the microphone 11. This rectified signal is continued by the Raisch circuit 30 processed, so that a noise voltage and a noise current result that are proportional the noise in the environment in which the device is operating. Are the noise voltage and the rectified signal is practically the same, i.e. there are no essential tones apart from the speech tones If there are signals surrounding speech, the output of the N / S! Comparator 40 is high the output of the transmission attenuator 13 to the transmission signal rectifier 16 and rectified. The signals from the output of the hybrid circuit 3 are sent to the received signal rectifier 24 where the signals are rectified. The rectified signals from the outputs the transmit and receive signal rectifiers and 24, which are referred to as Tx and Rx signals, respectively, are compared by the Tx / Rx comparator 60. The output of comparator 60 is high when the Rx signal is larger than the Tx signal; it is low when the Tx signal is about the same or about is larger than the Rx signal. The reference signal source 70 is used under the control of the potentials on the N / S and Tx / Rx lines 71 and 72 a variable To provide reference signal. The variable reference signal appears on line 74 while also a control signal is provided on the line 73 in order to control the noise current switch 45.

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A noise current is developed in the noise circuit 30, the one under the control of the noise current switch from that Output signal of the differential amplifier 50 via the parallel to the resistor 51 lying diode 52 and above the diode 53 is disconnected. So if the noise current switch diverts the noise current from this path, the Feedback around the differential amplifier essentially built up by the resistor 51, the amplifier 50 works as a voltage follower. Accordingly, this will be variable reference signal given on line 55. In the case where the noise current switch prevents current flow through the diode 53, the voltage at the output of the amplifier 50 is at a more poäfcivere value than the reference signal on line 7 ^ »by one Amount practically equal to the voltage drop in the forward direction across diode 52, which is parallel to resistor 51.

The control signal from the output of the differential amplifier 50 controls the transmission attenuator 13 and 13 the reception attenuator 21. In this embodiment, the attenuators 13 and 21 are conventional Type in which attenuation occurs by an amount equal to the logarithm of the difference between a pair of Corresponds to control voltages. The control signal from amplifier 50 varies in a range between a lower reference voltage in the transmission attenuator 13 and a higher reference voltage in the receive attenuator 21 lies. This means that the total sum of the respective attenuation is always a constant. If e.g. the transmission attenuator is controlled so that only a relatively low attenuation on the transmission channel 10 is exercised, the reception attenuator 21 is controlled so that on the reception channel 20 a relative high damping is exerted. In this case it is

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Device on transmission mode a jpstcllt. In the Fa ^- II ₁ in which the attenuation factors are in reference to the Dämpfuiigsglieder reversed, that is, with an increase of the potential of the control signal, the device is in the receive mode. If the transmission device receives only a small signal or no signal at all via the hybrid circuit 3 »and practically no speech signals are transmitted to the transmission device via the hybrid circuit 3, the control signal has such a potential that the respective attenuators 13 and 21 are kept at medium attenuation factors. In this case the device is set to free operation.

Receive transition add-on circuit 62 and receive transition delay circuit 67 are used to prevent unwanted or premature switching from receiving mode to prevent transmission operation. If the received signal from the received signal rectifier 24 greater than the transmission signal from the transmission signal rectifier 16, the potential of the output signal of the comparator 60 rises. The additional reception circuit 72 responds to positive signals at the output of comparator 60 by increasing the amplitude of the output signal of the received signal rectifier 24 amplified. This gain is relatively small in comparison with the typical speech signals coming from the rectifier 24 are included. In those cases in which the received signals have a relatively low amplitude, however, serves this amplification is used to switch the electroacoustic transducer to receive operation more reliably.

The transmission transition vex delay circuit 67 couples part of the signal from the output of the Tx / Rx! comparator 60 to the non-inverting input of N / S comparator 40 when that signal is high. Abweidhungen on

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a lower amplitude to be excluded from the non-inverting input of the! Comparators kO so that required in the receive mode a considerable size of the speech signal from the microphone signal rectifier l4 before the Ausgangssigiial of the comparator is Kom kO shifts to a low state. This low state, of course, indicates to the reference signal source that there is a substantial speech signal from the user of the device. The transmission transition delay circuit 67 acts to prevent incorrect switching to transmission mode when the device is used in an environment with a significant amount of acoustic echo or delay. As a result, the ends of the syllables and words transmitted by the loudspeaker 23, which are delayed and then picked up by the microphone 11, are ignored, so that the frequency of the invalid and undesired switchover to transmission mode is reduced.

According to FIG. 2, the output of the microphone signal ^{rectifier ί ι} ί is connected to the non-inverting input of a comparator 31. The cathode of a diode 32 is connected to the output of the comparator 31. The anode of the diode 32 is connected to the non-inverting input of a differential amplifier 35. A resistor 33 is connected between the non-inverting inputs of the comparators 31 ^and 35. A capacitor 3'i is connected between the non-inverting input of the comparator 35 and ground. The output of the differential amplifier 35 is connected to the base electrode of a transistor 38 via a resistor 37. The emitter electrode of the transistor 38 is connected to the inverting inputs of the Kompo * ators 3I and des

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Differential amplifier 35, to a resistor 39 a and connected to earth via a resistor 39.

During operation, the noise circuit according to FIG. 2 supplies the voltage and current signals for the ambient noise and the interference noises. The circuit responds very slowly to positive going signals and very quickly to negative going signals, so that a signal occurs at the output of the differential amplifier 35 which is essentially related to the ambient noise prevailing at the point on which the device operated :! will. The output signal is practically not influenced by the speech content in the signal from the microphone signal rectifier 14. The transistor 38 acts as an emitter amplifier. The signal from the output of the differential amplifier 35 wii-d is given to the base of the transistor 38 via the resistor 37, so that a corresponding voltage signal occurs at the emitter of the transistor 38. This signal or the noise voltage develops a current through the resistor 39 , which is linearly related to it j this current is then available as a noise current at the collector electrode of the transistor 38.

A positive sloping signal ar. the non-inverting Input of the comparator 31 charges the capacitor 34 slowly on through the resistor 33. The speed with which the capacitor 34 is charged is determined by the R-C time constant of capacitor 34 and resistor 33. The ones on that The voltage resulting in capacitor 34 is through the differential amplifier 35 amplified by an amount essentially related to a negative one

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Feedback voltage, that is, the noise voltage picked up at the resistor 39.

If a negative vez-running signal occurs at the non-inverting input of the comparator 31, its output signal becomes low, as a result of which the capacitor 34 is discharged via the diode 32. Thereby, the output of the differential amplifier 35 is rapidly decreased. Similarly, the voltage across resistor 39 is decreased at the same rate as the negative going signal until the feedback voltage and the signal at the input of comparator 31 are approximately equal. At this point in time, the output signal of the comparator 31 rises, whereby the further discharge of the capacitor 3 ^ is ended.

The differential amplifier 35 acts as an isolating amplifier. The resistor 37 is only installed to prevent a significant forward current through the base-collector junction of the transistor 38 in the event that the transistor 38 approaches saturation. This can happen if very high ambient noise occurs. Without the resistor 37, it would be possible for the noise current at the collector of the transistor 38 to be reduced by the current from the output of the amplifier 35, while the noise voltage developed remains as the output voltage from the amplifier 35. Thus, the transistor 37 essentially maintains the required relationship between the noise current and the noise voltage by preventing the transistor 38 from being over-saturated. In this embodiment, it is believed to be more essential to keep the noise voltage and current in a practical linear relationship than the infrequently occurring, very high ones

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Record ambient noise levels. The attack time constant, ie the sensitivity to positive signals, is determined by the resistor 33 and the capacitor Jk and is approximately 5 seconds. The trigger or release time constant, ie. the sensitivity to negative signals results in a practically immediate and instantaneous effect; in the overall effect it is equal to the release time constant of the modulator jA of FIG. 1.

Referring to Figure 3, Tx / Rx line 72 is anode one Diode 82 and connected to one end of a resistor 75. The cathode of diode 32 is connected to the base electrode a PNP transistor 8O connected. The other end of resistor 75 is connected to the anode of a diode 76 connected, the cathode of which is connected to the emitter electrode, of the transistor 8O via a resistor 8l, to ground a capacitor 77, to a control line 73, and across a resistor 38 to the base electrode of an NPN transistor 86 and the base electrode of an NPN transistor 87 is connected. The cathode of diode 76 is still with a terminal V, for the lower limit voltage connected via a resistor 78. The collector electrode of transistor 80 is connected to the voltage terminal V \. connected. The Bcis electrode of the transistor 8O is connected to the voltage terminal V via a resistor 84 tied together.

The N / S line 71 is to the anode of a diode 83, to the anode of a diode 93 and to one end of a Resistor 91 connected. The cathode of the diode 83 is connected to the base electrode of the transistor 80. The cathode of the diode 93 is connected to the base electrode of a PNP transistor 9 ° and to the voltage

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kleuirae V, connected through a resistor 94. The collector electrode of transistor 90 is connected to voltage terminal V ₁ . The other end of the resistor is connected to the anode of a diode 92, the cathode of which is in turn connected to the emitter electrode of transistor 90 via a resistor 9oa, to ground via a capacitor 95 and to the base electrode of an NPN transistor 96.

The collector electrodes of transistors 86, 87 and 96 are all connected to a voltage terminal V for the upper limit voltage. The emitter electrodes of the transistors 87 and 96 are jointly connected to the span :: uiigsklerame V via a pair of resistors 98 and 97 connected in series. The emitter electrode of the transistor 86 is connected to the node between the resistors 97 and 98 via a potentiometer 99. The output line fk for the reference signal is connected to the adjustable contact of the potentiometer 99.

The operating sequence of the circuit of FIG. 3 in connec tion using your entire device will be explained later.

Referring to Fig. 4, the output of the Tx / Rx comparator 60 of Fig. 1 is connected to the base electrode of an NPN transistor 63 connected through a resistor 64 in series with a capacitor 65 is connected. The base electrode of transistor 63 is also connected to ground via a resistor 66. The collector electrode of the transistor 63 is connected to the received signal rectifier 24, as shown in FIG. 1, via a resistor 63 a is connected.

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During operation, a positive voltage across the resistor 64 and the? Capacitor 65 transmitted to the base electrode of transistor 63, whereby transistor 63 is switched to the conducting: iden state. The potential at the collector electrode of the transistor 63 tends to the ground potential, and the resulting current pulse is drawn by the received signal rectifier 2'Jt. The duration of the current pulse is practically determined by the resistors 64 and 66 and the capacitor 65. It has been found that in this embodiment, a current pulse with a duration of between approximately 40-80 msec provides satisfactory results. The resistor 66 also serves to keep the transistor 63 in the non-conductive state under all conditions and states that occur;:, including a partially positive deviation at the output of the Tx / Ibi comparator 60.

As shown in Fig. 5, the output of the Tx / Rx comparator is 60 connected to the anode of a diode 68, the cathode of which is connected to one end of a capacitor 69 a and the non-inverting Input of the N / S comparator 40 is connected via a resistor 69 b. The other end the capacitor 69 a is connected to ground.

During operation, the capacitor 69 a rapidly charges through the diode 68 to the potential at the output of the Tx / Rx comparator 60. If this potential is reduced, the capacitor 69 a discharges in Direction of the potential of the noise voltage across the resistor 39 (see Fig. 2) at a slow speed , which is determined by the RC time constant of the

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Capacitor 65 a, resistor 69 b and resistor 39 a in FIG. 2 is determined. It has been found that with a time constant of approximately 100 msec satisfactory results can be achieved. Thus, in cases in which the noise voltage is relatively low, them at the non-inverting input of the N / S comparator '± 0 during the last operational sequence in the receiving mode and for a short, subsequent period of time a little reinforced.

According to FIG. 6, the shown rectifier is used as a microphone signal - rectifier 14, transmission signal rectifier 16 and received signal rectifier 24 are used. A functional amplifier 110 wa is one Input 112 for the connection of an AC-coupled input signal via an input resistor 113 with the entrance on. The anode of a diode Il4 is connected to the input 112, while the cathode of the diode II4 is connected to the output of the amplifier 110 is. A resistor II6 is connected between the input 112 and the cathode of a diode II5, whose Anode is connected to the output of the amplifier 110. The junction between resistor I16 and the diode 115 is connected to an output terminal 119 via a resistor 117. A capacitor II8 is between the Output terminal and earth switched.

During operation, there is a positive going to which Entry; 112 incoming input signal via the resistor 113 “the conductive state of the diode II4. In order to the gain factor is practically one. If the input signal is negative, the diode 115 conducts the Stx-om, where the gain of the amplifier practically by the resistance ratio of the resistors 113 and 116 is determined in a conventional manner.

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The combination of the resistor 117 and the filter capacitor II8 provides the required attack time in the rectifier. The release time is provided by a discharge path that includes resistor 117, resistor Il6 and diode Il4. For example, according to one embodiment , the RC attack time constant provided in the microfiberal rectifier lk is between 4 and 5 msec, while the time constants in the transmission and reception signal rectifier l6 and 24 are between 1 and 2 msec. The enable time constant in the transmission and reception signal rectifiers 16 and 24 is approximately 50 msec, while it is approximately msec in the microphone signal rectifier 14.

So far, a voice-controlled electro-acoustic is generally Communication system has been described, wherein different parts have been highlighted. If the microphone 11 is an electrostatic or condenser microphone, e.g. an electret microphone with a suitable, self-adjusting or adaptive circuit, so the embodiment shown is particularly good suitable to be in a single, enclosed unit be accommodated zti. In addition, this special Embodiment particularly favorable for telephone calls can be used in which the receiver does not have to be held by hand so that the hands are free for another activity. The operation of the connection device as a functional unit, e.g. via the connection terminals 2 is connected to a subscriber line or a network, the following is now summary description made with reference to the drawings.

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As the demands on the gain in transmission s and receiving channels for clektroakustischen converter such as an L _au thörgerät are much higher than in a conventional telephone subscriber device, the two channels can not be turned on at the same time, so be ON because the otherwise Connection device would start to vibrate due to acoustic coupling via loudspeaker 23 and microphone 11 and feedback coupling via hybrid circuit 3. The transmission and reception attenuators 13 and 21, which are also referred to as variolosser, that is, arrangements whose attenuation can be controlled by a voltage or a current, overcome this problem in the conventional way, ie by adding a channel switched on, i.e. ON, while the other is switched off, i.e. OFF. The degree of attenuation or loss switched in the Variolossem is just enough to keep the entire feedback loop veriärlcung of the connecting device a little below one.

In transmission mode, i.e. when a user of the device speaks, the transmission channel 10 is switched on by the transmission attenuator 13, the the amplified microphone signal via the hybrid circuit 3 to the connection terminals 2, i.e. the telephone part ■ teaching loop or lead, leads. The receiving channel 20 is switched off by the receiving attenuator 21, so that the microphone and line signals are prevented from appearing on the loudspeaker 23. In reception mode, i.e. when a person speaks at the other, far end of the line, the reverse occurs Switching process off, signals from the line to the loudspeaker 23 and the occurrence of microphone signals on the line are prevented. at

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The transmission and reception attenuators are free operation 13 and 21 each in a half-einzw. Half-off state held. Free operation is in the absence of essential, speech-like signals from the microphone and in the absence of essential signals from the line.

Since the state of the connecting device or the mode of operation is controlled by speaking, the control circuit speaks sensitive to the language enveloping secondary tones. In the case where the signal from the received signal rectifier 24 is higher than the signal from the transmission signal rectifier 16 is the output signal of the Tx / Rx comparator 60 on the line lies, high. This keeps the connecting device in receiving mode. Is the signal from the transmission signal rectifier 16 is approximately equal to or greater than the signal from rectifier 24, so is the output signal of the comparator 6O low.

The output of the N / S comparator 40 is only at The presence of signals from the rectifier 14 low which have speech-like envelope characteristics. The conditions lines 71 and 72 control the reference signal source 70 ·

Assuming that the connecting device is set to free operation, the output signal of the Tx / Rx is Comparator 60 low. The capacitor 77 is charged to the lower reference voltage via the resistor 78. If the transistors 41 and 44 are in the non-conductive state, the noise current represents the output potential of amplifier 50. Since the transistor 86 is not

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leiter.deu is in the state, no current flows through the potentiometer 99; because the transistor 96 is in the conductive state, the voltage at the junction of the resistors 97 and 98 is slightly higher than the lower reference voltage and occurs at the sliding contact of the potentiometer 99. The voltage at the output of amplifier 50 is thus the reference signal voltage on line Jk plus the voltage drop across diode 52 and resistor 5I1 caused by the noise current. This Steuerxgnalspaimung causes the transmission attenuator 13 in the half-switched state half-ON with a typical attenuation of about 10 db more than when the transmission signal is switched on, that is ON, while the reception attenuator 21 is half-switched half-OFF with a typical attenuation of about 37 db more than in the case when the receiving channel is switched on, i.e. ON.

If signals surrounding or enveloping the speech tones are picked up by the microphone 11, the output signal of the N / S comparator kO becomes low. The transistor 90 is brought into the conductive state, so that the capacitor 95 is discharged very quickly, whereby the transistor 96 is brought into the non-conductive state. This reduces the reference signal voltage on line 7k to the lower reference voltage. The output signal of the amplifier 50 is now prevented from assuming the lower reference voltage only by the noise current. The connection device is now set to transmission mode. As a result, the attenuation in the transmission attenuator is practically regulated in inverse relation to the background noises received by the microphone 11 in the room or the environment. Are the language-like, from the micro-

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Fön 11 recorded envelope signals to a value is reduced below the noise threshold at the N / S comparator 40, the output signal of the comparator increases 40 on, transistor 90 will be in the non-conductive Brought to the state, and the capacitor 95 charges slowly through the resistor 91 and the diode 92 on. This causes the terminal device to slow down in accordance with the resulting slow switch-on of the transistor 96 is brought back into the free mode will.

If ei 3 ¹¹ signal is received from the line via the hybrid circuit, which is effectively greater than the signal from the Ubertragungs-Dämpfuiigsglied 13, so the voltage at the output of the Tx / Rx Koraparators 60 increases. The capacitor 77 is quickly charged via the resistor 75 and the diode 76 to a voltage which is higher than the upper voltage limit. The transistor 86 is thus brought into the conductive state, the upper limit voltage being applied to one end of the potentiometer 99. The transistor 87 is also brought into the conductive state, the resulting current flow through the resistor 98, combined with the current flow in the potentiometer 99 j builds up the voltage at the junction of the three resistance elements; all currents flow through resistor 97. This voltage is approximately equal to the voltage that would result if the connecting device were to be operated free. This means that any voltage between the upper reference voltage and the free operation voltage is available at the sliding contact of the potentiometer. Correspondingly, the gain factor in the receiving channel can be set manually from free mode to full receiving mode. In reception mode, the noise switch is switched to ON and sets the

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Noise current in the shunt to the positive Voltage source + V; so the noise stream has none Effect on the output of amplifier 50. The control of the noise flow is in particular disabled so that the dial tone or other line noises emitted from the loudspeaker via an acoustic coupling to the microphone, will not automatically increase the gain in the tier channel 20.

If the signal on the line decreases or disappears substantially, the voltage aii at the output of the Tx / Rx! Comparator 60 returns to its low state; For example, if the transistor 80 is kept in the non-conductive state by the fact that the voltage at the output of the N / S! comparator kO is high, the capacitor 77 discharges very slowly through the resistor 78. As a result, the circuit slowly returns to idle mode. If, for example, an essential voice signal is received through the transmission channel 10, the transistor 80 is brought into the conductive state and the capacitor 77 discharges quickly through the resistor 81. So that the transistor 80 can be brought into the conductive state, both voltages at the outputs of the comparators 60 and ^ to must be low. In this case, the terminal equipment has quickly returned to the transmission mode.

As an example, in the following table for a device that is similar to the embodiment described above, the switching burst times before: one operating mode to another compiled.

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97

Operating mode

Delay Time

from

transmission

reception

free

free

transmission

reception

free

free about 0.4 sec.

transmission

Reception

reception

transmission

Transition period

about 1/2 second about 1 sec

about 35 msec

our ferry 2 ο me e c

about 22 msec

about 5 ° msec.

These transition times are laduiigs- primarily by the Zoitkonstanteil the up-and-discharge circuit paths determines the k belong to the capacitors 78 and 95 in Fig.. O ^ s extent or the amount of amplification in the transmission channel 10 is essentially influenced by the extent of the ambient noise that is present at the place of operation of the device when the device is in transmission or in free operation, as described above.

During the transition to receiving mode, the receiving transition additional circuit 62 generates a pulse as a function of the positive-going voltage at the input of the Tx / Rx! Comparator 60. The pulse width is determined by the resistors Gk tind 66 in combination with a capacitor 65. The pulse is inverted and shaped by the transistor 63 and limited in amplitude by the resistor 63 a. This pulse simulates a small burst of pulses from the line, but is negligible when compared to average line levels. this pulse amplifies weak line signals so that they appear like average voice line signals; this prevents a quick switch back to transmission mode immediately after entering reception mode.

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The transmission transition delay circuit 67 artificially increases or amplifies the noise threshold at the N / S comparator 40 during the receiving operation. Thus, at the ends of words or syllables, the capacitor 69 a discharges slowly through the resistor 69 b when the voltage at the output of the Tx / Rx comparator 60 becomes low. As a result, the threshold of the N / S comparator 40 slowly returns to a level determined by the ambient noise of the room. This amplification prevents impulses and reverberation from quickly forcing the closing device to transmit operation, since such a forced switchover leads to it ^^. can have the last syllables of the received words cut off. The duration and _{extent of} the threshold amplification is selected so that a typical conversation is very possible.

The reception transition additional circuit 62 and the transmission transition delay circuit 67 are not essential for the satisfactory operation of this described, voice-controlled connection device for an electroacoustic communication system. Your installation in the connection device, however, causes such an improvement that it is very positive for everyday use Results. This relates in particular to the effect of the delay circuit 67 · The random, however, infrequently occurring, invalid provisions on transmission operations that occur with some Operating environments occur are handled by the receiving transitional add-on circuit 62 practically eliminated.

The process by which the transmission channel is amplified 10 controlled by the ambient noise

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when the Airohlußgerät is in transfer mode can be found in general for all types of all-locking devices for electro-acoustic communication systems whether they are controlled manually or according to another method, although so far only the use of a preferred embodiment for a voice-controlled connection device was described.

- patent claims -

409841/0671

Claims (1)

241150] Claims Connection device for an electroacoustic communication system for connection to a transmission facility with a control arrangement which sends a control signal for the operation of the device during transmission operation and delivers when receiving operation, characterized by an arrangement (1 ^ 1,30) for Generation of a noise signal that is representative of the acoustic ambient noise at the place of operation is, and by an arrangement (45,52) for changing the Control signal in inverse relation to the sound signal when the device is set to transmission mode is to reduce the gain of the device accordingly, reducing the natural tilt of a User of the device to speak louder in a noisy environment than in a quieter environment, is compensated, so that a more constant speech signals gel on the transmission device is given. 2. Connection device according to claim 1, characterized through a transmission channel (10) for converting the acoustic signals into electrical signals, through a receiving channel (20) for converting the electrical signals into acoustic signals. whereby each channel (10, 20) has a variable attenuator (13, 21), the reception and transmission channels (10, 20) respond to the control signal, and where the product of the insertion losses of the attenuators (13,21) for setting the operating modes is practical & a constant, through a coupling 409841/0671 arrangement, whereby the signals from the transmission caxial (lO) on. the transmission facility and the
Signals from the transmission device are coupled to the receiving channel (20):;
relative signal sizes at the output of the transmission channel (10) and at the input; ^r a: -. g of the receiving channel (20) responds, ur.i to deliver the control signal at the output of the amplifier, through a device (^ ± 0) in
the control arrangement for the comparison of the
Transmission channel (10) received signals with a threshold value which is determined by the noise signal, whereby the presence of:.?. the transmission channel (10) are received and are above the threshold level, is displayed, and by a device (70) responsive to the signal processing device and to a display from the comparison device (^ iO) in the
Control arrangement for generating one between two
Limit values lying reference signal, wherein the reference signal from the output of the means (70) for generating the reference signal is given to the input of the amplifier, the reference signal has a potential which approaches a limit value which corresponds to the receiving mode when the signal processing means
indicates that the signal from the coupling arrangement
is effectively greater than the signal from the transmission channel (10), the reference signal still having a potential which approaches the other limit value corresponding to the transmission operation when the signal processing means indicates that the signal
of the transmission channel (10) effectively greater than
is the signal from the coupling arrangement, and where 409841/0671 finally in the case in which the signal processing is correct indicates that the signals are approximately the same size, the reference signal has a potential, that lies between the two limit values and one Free operation corresponds, so that the means (70) for generating the reference signal on an indication of of the comparison device C ^ O) responds when the reference signal the intermediate potential has to cause the potential of the reference religious to move in the direction of the change other limit value, causing the device to Transmission operation is brought. 3. Connection device according to one of claims 1 wire 2, characterized in that the arrangement (45) 52) for changing the control signal a Gegci'lcopplungs circuit (52) that see between the Output and an inverting; Input of the amplifier is connected, the impedance of the coupling circuit varies inversely with the noise signal, to reduce the gain of the amplifier in reverse re-.lation to the noise signal, and one Switch (45,53), which on the device (70) for generating the reference signal responds to the noise signal only on the coupling circuit to be given when the reference signal is in the range of the intermediate potential and the other limit value . 4. Connection device according to claim 2, characterized that the device (70) for generating the reference signal upper (Vu) and lower (Vl) reference signal terminals for the connection of the upper and lower reference voltages corresponding to the corresponding to one and the other limit value, first (99), second (98) and third (97) resistors, where 409841/0671 the third resistor (97) between the lower reference voltage source and the first and second Resistor is connected, and wherein the variable reference signal is obtained from the first resistor (99) a first control arrangement (86) to control the flow of current from the upper reference voltage terminal to enable the first (99) and third (97) resistance to the lower reference span: ai: ignklemme if the signal from the coupling circuit is effectively greater than the signal from the transmission attenuator (13) and a second control arrangement (87 »96) to control the flow of current from the upper reference coil terminal over the. second u: id third resistance to the lower reference terminal essentially to enable when practically only ambient noise signals to the Input of the transmission attenuator (l3) are present, and then essentially to enable when the signal from the coupling circuit effectively greater than the signal from the transmission attenuator (13) is. Connection device according to Claim 2, characterized in that the control arrangement further includes means (62) for temporarily determining the effective size of the signal processing arrangement signal received by the coupling circuit immediately after the transition to amplify on receiving mode, creating a signal of relatively small size at the input of the Receiving channel for a certain period of time appears to be larger than the signal from the transmission channel (10) to prevent a rapid fluctuation back to the transmission operation. 409841/0671 6. Connection device according to claim 2, characterized in that that the control arrangement further comprises means (67) to the To amplify the threshold value during reception operation and to reduce the gain relatively slowly after a transition from receiving mode, whereby the comparison device is practically there is prevented from responding to acoustic signals from the receiving channel (20) that are somewhat due to room reverberation be delayed. 7 method for controlling the operation of a connection device for an electroacoustic communication system, which is connected to a transmission device and on transmission mode and receiving mode can be set, each of which is determined by a control signal, as indicated by that a noise signal is generated which is representative of the acoustic background noise at the operating location, and that the control signal is changed in inverse relation to the sound signal when the device is in transmission mode works to reduce the gain of the device accordingly, reducing the natural tendency a user of the device to speak louder in a noisy environment than in a quieter one Environment, is balanced, so that a more constant speech signal level on the transmission equipment is given. 409841/0671 Blank page