NL194109C - Two-way link coupling chain for an electronic home telephone system. - Google Patents

Description

1 194109

Two-way link coupling chain for an electronic home telephone system

The invention relates to a two-way connecting line coupling circuit for use in an electronic home telephone system, comprising a connecting line for direct incoming and outgoing dialing (RIUK) and a coupling chain, which RlUK connecting chain is connected to a switching chain, and to the a- and b terminals of a central line can be connected, which coupling chain can be connected between the RlUK connection chain and a central processing unit of the home telephone system.

Such a chain is known from US-A-3,748,396.

10 In general, RIK (direct incoming dialing) is a method of connecting line for an automatic in-house telephone exchange system. In this case, an extension connected to a central telephone system (the caller) calls a specific extension of an automatic PBX by direct dialing (or dialing), which PBX has a RIK connection line. To call the PBX of the PBX , part of the number dialed in the main exchange is passed on to the shell exchange, which then directs RIK signals to the respective home appliance, ie

the person called, passes on. In other words, this means that incoming traffic for a home appliance within an automatic gateway can take place without the intervention of a main appliance. For outgoing traffic from a home appliance of such an automatic central exchange with a RIK connection line, the home appliance must occupy the outside line. However, this cannot be done directly over the RIK connector 20. This means that with a RIK line there is the difficulty that only incoming dialing, ie receiving, is possible through connection of the connecting line with the gateway system, so that no outgoing connection over the RIK line can be made from a home appliance of this system. formed.

In an ordinary telephone line with the loop power circuit, an incoming call cannot be processed in an automatic home telephone system, in which case an operator must first ask the main telephone the house telephone number over the telephone line, and then call the corresponding home telephone. Therefore, in an automatic home telephone exchange, the automatic processing of an incoming call in the case of a telephone line with loop current switching cannot take place, so that an operator is required, while, on the other hand, outgoing calls can be dialed over this line.

When performing couplings for RIK and loop power lines, as described in US-A-3,748,396, there is the difficulty that two types of connection lines exist, and that a corresponding operation must be selected depending on the operation.

In the European PTT-ALS-70 eteisei, this drawback can be avoided, however, high impedance coils are required, thereby increasing dimensions. To restore the balance of the transfer 35 signal on a line, large capacitors must be used, which further increases costs and dimensions

The object of the invention is to provide a coupling chain of the type mentioned in the preamble, which is automatically compatible for incoming and outgoing traffic without the intervention of an operator, which chain can select a called device for incoming and outgoing traffic.

For this purpose, the coupling circuit according to the invention is characterized in that the RlUK connection chain comprises - one or more transformers connected to the central line; - a speech path circuit incorporated between these transformers and the switching circuit; a large impedance determination circuit to which a large impedance signal can be received from the central terminal across the a and b terminals for supplying this signal to the coupling circuit; 45 - a changeover switch connectable to the transformers for making a choice between transmitting a large or a small impedance signal; - a relay supply chain for operating the changeover switch; means associated with this change-over switch for producing the large grater. small impedance signal; and 50 - a tone signal detecting / transmitting circuit included between the speech path and the coupling circuit for determining a tone signal and for transmitting the determined tone signal to the switching circuit.

It should be noted that the European PTT-ALS-70 system avoids the objection that there must be two types of connecting lines, and that depending on the operation, a corresponding operation must be selected, however, high impedance coils are required, increasing the size 55 To restore the equilibrium of the transmission signal on a line, large capacitors must be used, which further increases the cost and size 194109 2

The invention was explained in more detail below with reference to a drawing; Fig. 1 shows a block diagram of a known automatic home telephone system with a RIUK connector chain; Figure 2 shows a more detailed circuit diagram of the RlUK chain of Figure 1; Figure 3 shows a schematic representation of a chain according to the invention; and Figures 4A and 4B more detailed circuit diagrams of the RlUK signal detection / transmission chain of Figure 3.

Figure 1 shows a European PTT-ALS-70s \ e \ se \ schematically. In order to avoid the drawbacks thereof, it is known to use the circuits defined in figure 2 therein, wherein coils L1, 10 and L2 with high impedance are used. In order to align the balance of the transfer signal, it is then necessary to use capacitors C3 and C4, which must have a capacitance of at least 1 pF (100 V). All this leads to an increase in the dimensions and costs of the assembly. In the circuit of Figure 2, the block 91 is a surge protector circuit (to protect the system from a voltage over a certain value by protecting the voltage applied to the line), and the block 92 a circuit for forming of a large impedance (for passing on the result of determining the line impedance); blocks 93 and 94 are circuits for determining the state of the reverse and resp. forward loop, and the block 95 is a voltage boosting transformer.

Figure 3 shows a diagram of a chain according to the invention. The a and b terminals to be connected to a central line are connected to transformers T1 and T2 to adjust the impedance, and also to input terminals 5 and 6 of an RlUK signal determination / transmitter circuit 101 for determining a large impedance . A limited current from a current limiting circuit 121 flows to terminals 2 and 3 of the signal determining / transmitting circuit 101. A changeover contact SW1 is operated by a relay winding L1 under the control of a relay power circuit 107, in order to produce a signal related to a large resp. small impedance. When the signal at the terminal 4 of the circuit 101 flows through a diode D1 and a series resistor R1, a large impedance is formed, while a direct impedance is formed on direct output.

A large impedance sense signal at a terminal 14 of the signal sense / transmit circuit 101 is processed in a control circuit 109. The signal processed in this control circuit 109 is input through a buffer circuit 110 into a central processing unit 10 (CVE). A forward battery probe terminal 11 of circuit 101 is connected to a current source terminal Vcc through a resistor R7. A reverse battery probe terminal 10 of this circuit 101 is connected to a latch circuit 106, the reverse signal of which is passed through this interface circuit 106 to the central processing unit 10 and the control circuit 109. A circuit protection terminal 13 of the circuit 35 101 is connected to the control circuit 109. A busy detecting terminal 12 is connected to a latch circuit 108, whereby a busy signal is passed through the latch circuit 108 to the buffer chain 110 and further to the central processing unit 10 and the control circuit 109. The secondary windings of transformers T1 and T2 are connected to a talk circuit 102.

An output terminal of the talk circuit 102 is connected to a capacitor C6, to which is coupled a 40 tone signal detect / transmit circuit 104 through resistors R3 and R4. The input output terminal of the circuit 104 is coupled to a latch circuit 105, and is connected to the central processing unit 10 through the intermediary thereof and of the buffer chain 110. Chains 105, 106 and 108 are summarized in block 20 in Figure 1.

The relay power circuit 107 is turned on to energize the relay coil L1 in accordance with the output signal of the control circuit 109, so as to select a small or large impedance signal through the relay contact SW1. When comparing Figure 3 with Figure 1, the RlUK connecting line chain corresponds to the dotted line block 90, while the coupling chain of Figure 1 corresponds to the dotted line block 30. The central processing unit is designated by reference numeral 10.

First, the essentials of the invention will be briefly described. When a busy signal over a central line CO occupies a home telephone exchange, the RlUK connector circuit 90 inverts the polarity of the 48V voltage received over the telephone line from the exchange in the high impedance state, instead of a wake-up signal. Conventional loop current switching circuit, which notifies CPU 10 of incoming call, while controlling a 55 switching circuit 50 to build a speech path to a corresponding home appliance circuit 40. That is, before a two-tone modulation signal is received, the speech path must be connected, while, as in the RlUK coupling mode, a feedback or busy tone is formed in a tone circuit 60 3 194109. Since the speaking route has now already been set, it is not necessary to additionally communicate the free or occupied state to the central exchange. For later calculating the call costs in case the called home appliance is busy, a signal is sent to the central exchange over the central line CO.

5 In a known European home telephone system, a counting impulse is used for the call cost calculation. Without receiving the aforementioned signals, the home telephone exchange counts the number of counting pulses, a large impedance state communicating to the central exchange when the two-tone signals have all been received. The central exchange interrupts the transmission of these signals as soon as a large impedance condition is detected. In the case of calls, the RLUK circuit 90 selects only the 10 operating advantages of the loop current circuit, and this circuit operates in accordance with the loop current switching mode.

A preferred embodiment of the invention will now be described in more detail with reference to Figures 4A and 4B, in which a more detailed circuit diagram of the circuit 101 of Figure 3 is shown. The terminals 10 and 11 in Figure 4A are the correspondingly numbered terminals of this block 101.

When a connection line is occupied in the central exchange for calling a home appliance of an automatic gateway, a large impedance voltage reversal signal is first transmitted from the central exchange over the telephone line CL.

Since this transmitted signal is a large impedance signal, a determination circuit must therefore have an almost infinite input impedance.

As shown in Fig. 4B, the determination circuit comprises a computing amplifier OP1 having a differential gain operation against a comparison voltage. The output terminal of this amplified OP1 is connected via the diode D14 and a resistor R18 to the base of a transistor Q11, the collector of which is connected to a photocoupler PT3. The output terminal of the photocoupler PT3 is connected to a series circuit of a resistor R22 and inverters N13 and N14, thereby forming an output signal corresponding to the reversal signal. A transistor Q12 is made conductive by the tap voltage of a voltage divider R19-R20, with which a supply voltage of -48 V to a terminal 9 is reduced to -24 V, which is applied to the voltage terminal Vcc of the amplifier OP1. At the normal voltage polarity at the a and b line terminals 5 and 6, the a terminal is negative and the b terminal positive, so that the transistor Q11 turns in the absence of an output signal 30 from the amplifier OP1, and consequently the photocoupler PT3 is disabled. The output of the inverters N13 and N14 then becomes high, indicating the inactive state.

When occupying the gateway, the polarity at the a and b terminals 5 and 6 is reversed, and the a terminal 5 becomes positive and the b terminal negative, so that the input voltage at the amplifier OP1 35 is also reversed, and its output voltage is changed and goes low, so that the transistor Q11 becomes conductive. Thereby, current flows from the grounded voltage source terminal connected to the emitter of the transistor Q11 to the -48 V terminal 9 through the photocoupler PT3. When the light lead D16 of this photocoupler PT3 is energized, its phototransistor also becomes conductive, the collector of which obtains a low voltage. This low state is not changed after passage 40 through the reversing stages N13 and N14. As can be seen from Figure 3, the low voltage signal is sent to the control circuit 109 and processed through the buffer circuit 110 in the CPU 10. As shown in Figure 1, the CPU 10 controls the tone circuit 60 through the interface circuit 30 to produce a dial tone, while the switching circuit 50 passes the dial tone to the central office. A two-tone signal is received in a receive circuit 70 through the intermediary 45 of the RlUK circuit 90 and the switching circuit 50, and sent to the CPU 10. When a two-tone signal is received from the central exchange at a busy home appliance or in the case of an incorrect or unauthorized telephone number, a large impedance signal is sent to the central exchange in response to the dialed number. Block 100 is a coupling line circuit.

In the aforementioned case, the control circuit 109 controls the relay power supply circuit 107, energizing the 50 relay coil L1 and bypassing the relay contact SW1 to position 1. The contact 1 is connected to the resistor R1 and the diode D1, which, on the other hand, are connected to the forward input terminal 4, which is also shown in Figure 4A, so that a large impedance signal is sent to the main office. This signal passes through a diode D24 shown in Figure 4A from the a terminal and through the resistor R1 and the diode D1 as well as the input terminal 4. A photocoupler PT2 is then turned on, 55 with the current flowing through the output terminal 3 of the circuit 101 flowing to the current limiting circuit 121 is limited.

This limited current is sent to the reverse power supply terminal 1 through the input terminal 2 of the circuit 101 and a diode D1 1, so that a large impedance signal is sent through the transformer T2 to the b-terminal of the telephone line. During RIK operation, this is a chain for sending a reception signal to the central exchange, once the gateway has received all the numbers from the central exchange over the telephone line, or when the RlUK chain 90 receives an incorrect 5 or an unauthorized number, and therefore no digit information is needed anymore.

Before the large impedance signal transmit state occurs, the relay power circuit 107 is brought into the called state, with the relay changeover contact SW1 entering position 2 to form a low impedance loop. This state means that the CPU 10 is in a two tone signal detecting state under the control of the two tone signal receiving circuit 70.

10 When the CPU 10 no longer has to receive a two-tone signal, the changeover contact SW1 is brought into position 1 via the relay supply chain 107. A large impedance loop is then formed again by means of the resistor R1 and the diode D1, and a corresponding large impedance signal is placed on the telephone line.

This signal is maintained until the user of the called device 120 hears the alarm tone generated by a wake-up circuit 130 and picks up the receiver, as follows from Figure 1. At that time, a feedback tone from the circuit 60 is received by the talk circuit 102 of the RlUK circuit. 90 to the switching circuit 50 connected to the speech path, and then sent to the telephone line through the transformers T1 and T2. The transmit operation of the large / small impedance signal in the detect / transmit circuit 101 will be described in more detail.

The current flowing through the current limiting circuit 121 is limited by the diode D24 and a resistor R12 depending on the position 1 or 2 of the changeover contact SW1 for selecting a large resp. small impedance. The limited current flows through the diode D11 and the terminal 1 to the a-terminal of the telephone line. In this case, the current does not exceed about 3 mA, which is determined in the main power plant. The conversation then begins, and the speech in the central exchange is connected. This large impedance state is the feedback tone transmit state, and when the signal is processed, the telephone conversation can begin.

In the case of an incoming connection to the RlUK circuit 90 or the occupying of the circuit 90 for an outgoing call by the gateway, the small impedance signal forms a speech path, while the current flowing through the circuit 90 through the main station is the small impedance state. is adopted. In FIG. 3, when the changeover contact SW1 is in position 2 by energizing the coil L1 connected to the relay power circuit 107, the current flowing in the current limiting circuit 121 through the diode D24, the photocoupler PT2 and the terminal 3 30 mA limited. The current thus limited in the circuit 121 flows through the diode D11 to the transformer T2, thereby applying a small impedance state signal to the b-terminal of the central line. In contrast to the aforementioned transmission, the small impedance reversal signal in the transformer T1 is sent across the a-terminal, across the terminal 4 and the relay contact SW1 in position 2 to the circuit 101, which signal is then passed through the diode D24 to the coupler PT2 is running. The signal passing through the photocoupler PT2 is limited in the current-limiting circuit 121 across terminals 3 and 2, after which it passes over diode D11 to transformer T2. This signal then passes to the b-wire of the telephone line.

The emitter voltage of the phototransistors of the photocouplers PT1 and PT2 is reversed, depending on the driving state thereof, by means of resistors R14 and R15 by inverters N11 and N12. Therefore, a reverse battery signal at terminal 10, and a forward battery signal at terminal 11 are determined. When the two signals are received, and one of them is in the low state, an AND gate AN11 produces a low output signal, which produces an occupancy signal in an AND gate 45 AN12. This is produced regardless of the output of AN13, which depends on the state of the protective terminal 13 and the signal passed through an inverter N15.

After transmitting a small impedance signal over the center line in the aforementioned manner, this is determined in the center. The exchange then switches on the speaking route.

50 In view of the speech path connection and regardless of the state of the loop relay, only a timer is switched on and off in the switching circuit 50, enabling transmission / determination of a tone and a two-tone signal. The tone signal detect / transmit circuit 104 of Figure 3 performs the task of the two tone transmit / receive circuits 70 and 80 and the tone circuit 60.

As described above, a RlUK chain is provided which allows two-way dialing. This has the advantage of allowing easy coupling to a conventional exchange, thereby improving reliability and simplifying installation work.

Claims (8)

A two-way link chain for use in an electronic home telephone system, comprising a direct incoming and outgoing dialing link (RIUK) and a link chain, which RLUK link is connected to a switching circuit, and to the a and b terminals of a central line can be connected, which coupling chain can be connected between the RlUK connection chain and a central processing unit of the home telephone system, characterized in that the RlUK connection chain comprises - one or more with the central line (CO ) connected transformers (Γ1, T2); 10. a speech path circuit (102) included between these transformers and the switching circuit (50); - a large impedance determination circuit (101) to which a large impedance signal can be received from the central line over the a and b terminals for supplying this signal to the coupling circuit (30); - a changeover switch (SW1) connectable to the transformers for making a choice between transmitting a large or a small impedance signal; - a relay power circuit (107) for operating the changeover switch (SW1); - means (R1, D1) connected to this change-over switch for generating the large or small impedance signal; and - a tone signal determination / transmit circuit (104) included between the speech path (102) and the coupling circuit (30) for determining a tone signal and for transmitting the determined tone signal to the switching circuit (50). Coupling circuit according to claim 1, characterized by a plurality of latching chains (105, 106, 108) for locking data according to the large and small impedance signal and the determined tone signal, by a control circuit (109) for controlling the relay power circuit (107 ) and generating a control signal for controlling the RlUK link (90), and by a buffer circuit (110) for buffering the control data to be transmitted between the RlUK link (90) and the central processing unit (10) . Coupling circuit according to claim 1, characterized in that the large impedance fixing circuit (101) has a fixing circuit for determining a voltage inversion state at the a and b terminals of the central line (CL), as well as a forming circuit for amplifying the determined signal from the determining circuit and converting it into a large impedance signal. Coupling circuit according to claim 3, characterized in that the determining circuit comprises a current source for generating a comparison voltage for the output level of the determining signal. Coupling circuit according to claim 3, characterized in that the transforming circuit further comprises a photocoupler 35 (PT3) for transmitting the determination signal 5 194109 Coupling circuit according to claim 1, characterized by a current limiting circuit (121) included between the transformers (T1, T2) and the means (R1, D1) for generating the large / small impedance signal, for limiting the a smooth flowing stream. Coupling circuit according to claim 6, characterized in that the current limiting circuit (102) comprises photocouplers 40 (PT1, PT2) for transmitting current flow, as well as a circuit for generating reverse and forward battery signals for converting the output signals from the photocouplers in these battery signals. Coupling circuit according to claim 7, characterized by a circuit for generating a busy signal by deriving this busy signal from the output signal of the chain to generate 45 forward and backward battery signals using an output signal of a chain protection device (13 ). Hereby 5 sheets drawing