NL8005113A - ELECTRONIC SIGNALING DEVICE FOR CONNECTION TO A SIGNAL TRANSMISSION LINE. - Google Patents

Description

If. , -Ti 11.9.1980 1 PHQ 79-018

Electronic signal device for connection to a signal transmission line.

The invention relates to an electronic signal device for connection to a signal transmission line over which the device is supplied with a DC supply current, which signal device comprises a number of switching units, each of which is provided with a pair of supply terminals for receiving a DC supply current.

An arrangement of this kind is, for example, a speakerphone, which contains different switching units, such as a voice-activated switch, a power amplifier and an electronic fork switch.

These switching units require a certain operating supply voltage for their operation. In order to make the best use of the DC supply current for the power amplifier, it is desirable to power the power amplifier in series with the other circuit units. The operating supply voltages of the circuit units then add up, so that there is a risk that a certain maximum, which is just permissible, will be exceeded.

In many automatic telephony systems, it is required that the voltage between the terminals of the telephone set 20 should not exceed a certain value under "worst-case" conditions, at a certain value of the DC supply current.

The latter determined value may be less than the sum of the operating supply voltages of the switching units, as a result of which the said requirement is not met under worst-case conditions.

The object of the invention is to provide an electronic signal device of the type stated in the preamble, with which the requirement that the voltage between the terminals of the device in "worst-case" conditions at a determined value of the DC supply current, must not exceed a certain value.

The electronic signal device according to the invention is characterized in that the supply terminals of at least two switching units are connected so that the supply current flows in series through the switching units and adds up the supply voltage of the one switching unit. the supply voltage of the other circuit unit and means are present which, when the DC supply current drops below a certain value, causes the supply voltage of at least one of the switching units to decrease more than proportional to the DC supply current.

The invention and its advantages will be described with reference to the drawing.

Fig. 1 is a block diagram of an apparatus according to the invention.

Fig. 2 is a voltage-current diagram illustrating the operation of the device according to the invention.

Fig. 1 shows the block diagram of a loudspeaking telephone set, which is a typical example of an electronic signal device of the present kind.

The invention will be elucidated on the basis of the loudspeaking telephone set, it being understood that the invention is applicable to other electronic signal devices, which contain a number of switching units which are fed by means of the signal transmission line.

The loudspeaking telephone set according to FIG. 1 contains a pair of terminals 1 and 2 for connecting the device to a signal transmission line, for example a subscriber's line of an automatic telephone system. The telephone set is adapted to receive a DC-25 supply voltage which is supplied to the set by means of the signal transmission line. In the case of a telephone exchange subscriber line, this DC supply voltage originates from the central battery of the telephone exchange. It is usual in this case that the subscriber's line is connected to the central battery by means of a pair of resistors, which are called power supply resistors.

To make the telephone independent of the polarity of the DC supply voltage of the signal transmission line, a rectifier bridge circuit 3_ is connected between the terminals 1 and 2 and the further circuits of the telephone. This rectifier bridge ensures that the voltage of conductor 4 will always be positive with respect to the voltage of conductor 5. Conductors 4 and 5 carry the supply current of the circuits of the telephone set, which flows from conductor 4 to conductor 5 and simultaneously the 8005113 11.9.1980 3 PHQ 79-018 leads 4 and 5 the other signal flows caused by speech and / or signaling signals.

It is to be understood that the block diagram of Figure 1 shows only a few important circuit units of a loudspeaker telephone. These can be supplemented with other switching units to perform other functions. However, the invention can be explained with the aid of the circuit units shown,

It is further understood that the invention is not concerned with the precise construction of the circuit units from which a loudspeaker telephone is constructed. The invention relates to the DC supply of the circuit units. A representation of the circuit units in block form will then suffice to explain the invention.

The loudspeaking telephone set of Fig. 1 contains an active fork circuit 6, a duplex switch 7 and a power amplifier 8.

The fork circuit 6 is provided with a pair of supply terminals 6-1 and 6-2. The duplex switch 7 is provided with a pair of power supply terminals 20-1 and 7-2. The power amplifier 8 is provided with the supply terminals 8-1 and 8-2. The supply terminals are interconnected so that the supply current flows in series through the switching units and the supply voltages of the switching units add up.

Loudspeaker telephones are known per se, as is shown, for example, by US patent 3,751,602 and US patent 4,052,562,

The fork circuit 6 further comprises a connection for a transmission path 9 and a connection for a reception path 10. Voice signals are applied to fork circuit 6 by means of transmission path 9. These 30 speech signals cause signal currents to flow between terminals 6-1 and 6-2, whereby a signal current flows between terminals 1 and 2. Speech signals from the signal transmission line cause signal currents to flow between power terminals 6-1 and 6-2.

These signal flows cause the appearance of speech signals on the receiving path 10,

The embodiment of fork circuit 6 is not important for the understanding and application of the invention. It is sufficient to know that fork circuit can contain 6 active elements in the form of 8 0 0 5 1 1 3 11.9.1980 4 PHQ 79-018 operational amplifiers and transistors, which for their proper operation require a DC supply current, which is derived of the power terminals 6-1 and 6-2. A possible embodiment of fork circuit 6 is illustrated in Fig. 3b of the aforementioned U.S. Patent 5 3,751,602, it being understood that the power supply terminal 6-1 would be connected directly to the collector of the transistor illustrated therein and the power supply terminal 6-2 by would be connected to the emitter of the same transistor by the resistance shown therein.

The duplex switch 7 provides a transmission path between the IQ microphone 11 and the transmission path 9 or between the receive path 10 and the loudspeaker channel 12. The duplex switch 7 contains circuits which, depending on the signals coming from the microphone 11 and receive path 10, enter a transmission path in one direction, from microphone 11 to transmission path 9, or in the other direction, from reception path 10 to loudspeaker 12, establishes 15.

The embodiment of duplex switch 7 is not important for the understanding and application of the invention. In principle, any known duplex switch can be used. A particularly suitable embodiment is illustrated in Fig. 11 of the aforementioned US Patent 4,052,562, with the proviso that one of the loudspeakers illustrated therein and the associated power amplifier would be replaced by transmitter path 9 and the microphone associated with the loudspeaker replaced would be by way 10; the remaining power amplifier with the loudspeaker connected to it would correspond to power amplifier 8 and the loudspeaker 13 and the microphone associated with the loudspeaker would correspond to microphone 11.

The electronic circuits in the duplex switch 7 require a DC supply current for their proper operation, which is derived from the supply terminals 7-1 and 7-2. The supply voltage between the power supply terminals 7-1 and 7-2 is stabilized by the Zener diode 14, which is connected in parallel to the power supply terminals. The AC impedance of Zener diode 14 is very low, so that the AC signal currents flowing between the supply terminals 6-1 and 6-2 of the fork circuit 6 will flow through the Zener diode.

The power amplifier 8 amplifies the speech signals which are supplied to the amplifier by means of the speaker channel 12. The DC supply current is taken from supply terminals 8-1 and 8-2. The supply voltage between these supply terminals is stabilized by the series connection of the Zener diodes 15 and 16, which is connected in parallel to the supply terminals. These Zener diodes detour for the AC signal flows in the same manner as Zener diode 14.

An important reason for connecting the 5 supply paths of the switching units 6, 7 and 8 in series is that in this way the DG supply current of the telephone can be fully utilized for power amplifier 8. A drawback is that the supply voltages of the add circuit units together.

In a practical automatic telephone system, the DC-10 voltage between terminals 1 and 2 of the telephone, at a certain value of the DC supply current, must not exceed a certain value. For example, the mentioned voltage should not exceed approx. 18.5 Volt at 15 mA, assuming a telephone exchange with a central battery voltage of at least 42 Volt, a pair of 15 power resistors with a common resistance of maximum 1000 Λ, a line length of maximum 2 km and a line current threshold of 15 mA.

The stated values, which occur jointly in the worst case (worst case), lead to a maximum permissible terminal voltage at the given threshold value of the line current. If this voltage value is used as a guide value also in the case that the DC supply current is greater than the threshold value, this leads to a limitation of the supply voltages of the switching units. The design of the circuit units then becomes more difficult or the operations thereof decrease. The latter is especially true for the power amplifier 8.

According to the invention, a circuit is provided which detects the DC supply current and which decreases the supply voltage of the power amplifier 8 more than proportional to the supply current when the supply current approaches the threshold value. The supply voltage V of power amplifier 8 as a function of the supply current i of the telephone set has the course as illustrated in Fig. 2. The threshold value is, for example, at 15 mA the supply voltage is, for example, 4.5 Volts, while for larger supply currents the supply voltage is for example 10 volts.

The supply voltage of the active fork circuit 6 and the duplex switch can together amount to, for example, approximately 12.5 Volts, which together with the supply voltage of, for example, 10 Volts of 80 0 5 1 1 3 11.9.1980 6 PHQ 79-018 power amplifier 8 and the voltage drop across rectifierburg 3_ provides a clamping voltage of approx. 24 Volt between terminals 1 and 2.

The decrease in the supply voltage of the power amplifier 8 from 10 Volt for currents greater than 15 mA to 4.5 Volt at the threshold value of 15 mA ensures that the terminal voltage at the threshold value does not exceed the maximum permissible value of 18.5 Volt. The deterioration in the quality of the speech reproduction by the loudspeaker in the worst case, which occurs only rarely, is accepted because of a good quality loudspeaker reproduction under normal circumstances.

The current sensing circuit contains, inter alia, transistors 17, 18 and 19. A current of approximately 1 mA flows through transistor 17, which is set by means of resistor 20. This current also flows through transistor 18, which is connected as a diode. and the resistor 21 15 of about 300SI in series. The voltage across transistor 18 and resistor 21 in series is then approximately 900 mV.

The phone's power supply current flows through resistor 22 of about 18Ω, which for AC signal currents is bridged by capacitor 23. The said voltage of 900mV is across the series-20 circuit of the base-emitter junction of transistor 19 and resistor 22. The transistor 19 then conducts when the supply current becomes less than about 16.5 mA. In this case, capacitor 24, which normally forms a buffer for the supply of power amplifier 8, is discharged by transistor 19. The current which is ultimately supplied by transistor 19 to resistor 22 is such that the sum of the voltages across the base emitter junction of transistor 19 and resistor 22 balances said voltage of 900 mV.

The result of the operation of the current sensing circuit is that when the DC supply current which flows between the terminals 1 and 2 (the line current) decreases, the supply voltage of the power amplifier 8 decreases so much that when the line current threshold the maximum permissible terminal voltage is not exceeded. The power amplifier can then be sized for a supply voltage which is greater than the supply voltage which is at worst allowed at a line current of 15 mA.

80 0 5 1 1 3

Claims (2)

1. Electronic signal device for connection to a signal transmission line over which the device is supplied with a DC supply current, which signal device comprises a number of switching units, each of which is provided with a pair of supply terminals for receiving a DC supply current, characterized in that the supply terminals of at least two switching units are connected such that the supply current flows in series through the switching units and the supply voltage of one switching unit adds to the supply voltage of the other switching unit and means are present which decrease the DC supply current. below a certain value the supply voltage of at least one of the switching units decreases more than proportional to the DC supply current. 2. Electronic signal device according to claim 1, characterized in that the main current path of a transistor is connected parallel to the supply terminals of at least one of the circuit units and means are provided for controlling the transistor by the difference between a reference voltage and a the DC supply current proportional voltage. 20 25 30 t 35 8005 113