DK176293B1 - Through-selection circuit - Google Patents

Description

DK 176293 B1

The present invention relates to a dial-up circuit in an electronic telephone exchange system and in particular to a DIOD (Direct Inward Dialout) circuit as a dial-up circuit.

In general, DID (Direct Inward Selection) is one particular method of mainline interface in a private, automatic sideline telephone exchange system. This is an interface method in which a specific subscriber (a calling party) on a master exchange in a master exchange system by direct selection calls a predetermined local subscriber in a private, automatic sideline telephone exchange system which has a DID outline. To call the local subscriber in the private, automatic sideline telephone exchange system, part of the number of the 10 main central line subscriber who chooses is recognized in the private, automatic sideline telephone exchange system, which directly calls the corresponding local subscriber, ie. a named party. In other words, this feature means that with respect to incoming traffic, local calls within a private, automatic sideline telephone exchange system can be made without any operator. Outgoing traffic from the line in the private, automatic telephone exchange system, which has the DID main line, means that the line must seize the main central line. At this time, it cannot directly grab the main center line via the DID main line. That is, the DID main line has a problem in that only incoming choices, i.e. reception is possible by connecting the main line ten! the private, automatic sideline telephone exchange system, so that a certain local subscriber in the private, automatic sideline telephone exchange system can not make an outgoing call via the DID line.

In a loop speed main line, an incoming call cannot be processed in a private, automatic sideline telephone exchange system, so that an operator hears a local telephone call number from the calling subscriber via the main central line and calls the corresponding local connection. In the private, automatic sideline telephone exchange system, the automatic process for an incoming call cannot take place by the loop-start mainline interface method, so an operator is needed, and for outgoing calls an operator can select through a loop-start main line.

Upon realization of the DID and loop-start mainline interface procedures as set forth in 30 U.S. Pat. U.S. Patent No. 3,748,396, there is a problem in that two types of main lines are both taken and the corresponding function is applied selectively when necessary.

In order to solve the above-mentioned common problems, the circuit designed as shown in Fig. 2 is supplied to the European PTT ALS-70 system as shown in Figs. The design, as for example in Fig. 2, should use coils L1 and L2 which have large impedances, which makes their dimension larger. To adjust the balance of the transmission signal on a line, capacitors C3 and C4 are required to be larger than at least 1 F / 100 V, so that there is a problem with increase in price and increase in volume.

2 DK 176293 B1

The object of the invention is to designate a DIOD (Direct Inward Outward Election) by-election circuit.

It is another object of the present invention to provide a circuit which is automatically compatible with inbound and outbound traffic without an operator,

It is a further object of the present invention to provide a circuit which can select a named subscriber by inbound and outbound dialing.

According to one particular aspect of the present invention, a throughput circuit in a DIOD main line circuit in a private, automatic sideline telephone exchange system comprises a control element for controlling said direct inward outward throughput circuit, an interface element for activating signal and data transmission between said control element. and said direct select circuit, transformers to be connected to a main central line, a taiwis element to be connected to said transformers, a high impedance detection element coupled to said main central line for detecting an input high impedance signal and supplying said detected signal to said interface element, a high / iav impedance signal generating element for generating a high / iav impedance signal, a switch 20 to be connected to said transformer in order to select whether high / iav the impedance signal must be sent or not, a relay control circuit for controlling the switching of said switch, as well as a tone signal detector / transmitter element to be connected to said voice path element for the purpose of detecting / transmitting the tone signal.

The invention will be explained in more detail below in connection with the drawing, in which Fig. 1 shows a usual block diagram of a private, automatic sideline telephone exchange system which has a DIOD main line circuit, Fig. 2 a detailed circuit diagram of a DIOD main line circuit as it is. shown in Figs. 1, 30 Fig. 3 is a circuit diagram according to the present invention, and Figs. 4A and Fig. 4B are detailed circuit diagrams for a DiOD signal detector / transmitter circuit as shown in Fig. 3.

Fig. 3 shows a circuit diagram according to the present invention. Bushing and ring terminals connected ten! a main central line, is connected to transformers T1 and 12 for impedance tuning and is connected at the same time to input terminals 5 and 6 for sensing the high impedance in a DIOD signal detector / transmitter circuit 101. The limited current in a current limiter circuit 121 flows into the current limiting supply terminals 3 DK 176293 B1 2 and 3 in DIOD signal detector / transmitter circuit 101. In switch SW1 is controlled on / off by the control of a relay drive circuit 107, whereby the generation of a high / low impedance set is selected. signal. When a signal generated via a terminal 4 in the DIOD signal detector / transmitter circuit 101 is generated via a diode D1 and a resistor R1, a high impedance is generated, and when it is output directly, low output is generated and transmitted. impedance.

A high impedance detecting output from the high impedance output terminal 14 of the DIOD signal detector / transmitter circuit 101 is processed in a control circuit 109. The high impedance detection signal, which is processed in a control circuit port 109, is input to a CPU 10 via a buffer circuit. 110. A forward battery sensor terminal 11 in the DiOD signal detector / transmitter circuit 101 is connected to a power supply terminal Vcc via a resistor R7. Its backward battery sensor terminal 10 is connected to a latch circuit 106 so that the rear sensor signal via the latch circuit 106 is input to the CPU 10 and the control circuit 109. A printed circuit board protective terminal 13 in the DIOD signal detector / transmitter circuit 101 is connected to the control circuit. 15 et 109. Its busy detection terminal 12 is coupled to a latch circuit 108 so that a busy signal passes a buffer circuit 110 via the latch circuit 108 and is input to the CPU 10 and the control circuit 109. The secondary sides of the transformers T1 and T2 are connected to a speech circuit. 102.

An output terminal in the speech circuit 102 is connected to a capacitor C6, to which a tone signal detector / transmitter circuit 104 is connected via resistors R3 and R4. The input / output terminal of the tone signal detector / transmitter circuit 104 is coupled to the latch circuit 105, whereby it is connected to the CPU 10 via the buffer circuit 110.

The relay drive circuit 107 is driven to excite the relay coil L1 in accordance with the output of the control circuit 109, whereby a low / high impedance signal is selected and supplied by the operation of the switch SW1. That is, in FIG. 3 compared to FIG. 1, the DIOD main line circuit corresponds to the dotted line block "90", and the interface circuit is equivalent to the dotted line block "30", and the CPU is "10".

First, the practice of the present invention will be briefly described. When a grab signal holds a private, automatic branch branch telephone system via a main exchange line c, o., The DIOD circuit 90 inverts a polarity from the 48 volt power supply supplied from the main exchange line c.o. in high impedance mode, instead of ringing in a usual loop start main line, whereby the CPU 10 is notified of incoming calls and controls the switch circuit 50 to set a voice path to a corresponding subscriber circuit 40 via the switch circuit 50. That is, before a DTMF signal is received, the telecommunication path should be connected, and the callback tone or busy tone in the tone generator circuit 60 is provided similar to the DID interface method 4 DK 176293 B1. Since the voice path has already been set, it is not necessary here to further inform the central exchange system about free or busy state. However, for the purpose of charging the caller later, when the called local subscriber has hung up, a signal is delivered to the main exchange via the central line c.o ..

In a conventional European, private, automatic sideline telephone exchange system, a measurement pulse is used for charging. Without receiving the above signals, the private sideline telephone exchange system counts the number of measurement pulses, and a high impedance state informs the master exchange system of when the DTMF signals aile have been received. The central control system stops the transmission of the DTMF signal when the high impedance state has been recognized. In the case of calls, the DIOD main line circuit 90 selects and applies only the benefits of functions during loop start and behaves in the same way with the mode of operation during loop start.

A preferred embodiment of the present invention is described in detail with reference to Fig. 4, which is a detailed circuit corresponding to the DIOD signal detector / transmitter circuit 101 shown in Figs. 3. When a central exchange subscriber seizes a central exchange line to call a subscriber in a private, automatic side branch exchange central exchange system, a high impedance polarity inverting signal is first sent from the central exchange system via the main exchange central line c.o ..

Since the transmitted signal is a polarity inverting signal of a high impedance, it is required that a detecting circuit therefore have an almost infinite input impedance.

As shown in Fig. 4B, the detecting circuit uses an operational amplifier OP1, which has a differential amplifier function as well as a comparator function. In addition, the output terminal of the operational amplifier OP1 is connected via a diode D14 and a resistor R18 to the base of a transistor G11, the collector of which is connected to a photocoupler PT3. The output terminal of the photocoupler PT3 is connected to a resistor R22 as well as the series-connected inverters N13 and N14, whereby a detecting output is produced with a high-impedance polarity inverting signal. A transistor G12 is opened by means of the split voltage between the resistors R19 and R20, whereby the supply voltage on the -48V terminal 9 is voltage divided in order to supply -24V to the voltage terminal Vcc on the operational amplifier OP1. At voltage polarities normally supplied to the socket and ring terminals 5 and 6, and if the socket terminal 5 becomes negative and the ring terminal 6 becomes positive, the transistor Q11 is turned off when no output comes from the operational amplifier OP1, and in accordingly, no signal comes through the photocoupler PT3. As a result, the outputs of the inverters N13 and N14 get a "high" state, thereby entering the idle state.

5 DK 176293 B1 In the meantime, when the private, automatic side branch telephone exchange system is to be seized and when power supply polarities are delivered ten! the socket and ring terminals 5 and 6, and if the socket terminal 5 is positive and the ring terminal 6 becomes negative, the input polarity of the operational amplifier OP1 is changed, i.e. the output polarity of the operational amplifier OP1 is changed. Accordingly, the output polarity of the operational amplifier OP1 is given a "low" state, thereby opening the transistor Q11. At this time, the grounded power supply in the emitter of transistor Q11 sends current to the -48v terminal 9 via the photocoupler PT3.

When a light emitting diode D18 in the photocoupler PT3 is opened, the phototransistor is opened and the collector gets "low" state. The "Low" mode is not changed by passing the inverters N13 and N14. And as shown in Fig. 3, the "low" state signal is input to the control circuit 109 and is sensed in the CPU 10 via the buffer circuit 110. Accordingly, as shown in Fig. 1, the CPU 10 controls via the interface circuit 30 the tone generator circuit 60 to generate the dial tone, and the switching circuit 50 to send the dial tone to the main subscriber's line subscriber. And a DTMF signal 15 is received in a DTMF receiver circuit 70 via DIOD main line circuit 90 and switch circuit 50 and is sent to the CPU 10. meanwhile, when the DTMF signal from the main exchange system is completely received in accordance with an associated extension, If an unwanted number or an unauthorized number occurs, a high impedance signal is sent to the central exchange system as a received signal for the number.

20

That is, in the above case, the control circuit 109 controls the relay drive circuit 107, whereby the coil L1 is driven and thus the switch SW1 switches to the position 1. At this time, the position 1 is connected to the resistor R1 and the diode D1 is connected to the forward input terminal 4, shown in Fig. 4A, so that a high impedance signal is sent to the main exchange system.

That is, the signal passes the diode D24 shown in Fig. 4A from the socket terminal via the resistor R1 and the diode D1 as well as the forward input terminal 4. Then the photocoupler PT2 is driven and the current flowing to the current limiting circuit 121 via the output terminal 3 for DIOD signal detector / transmitter circuit 101, becomes limited.

The limited current is supplied to the reverse voltage supply terminal 1 via the input terminal 2 of the DIOD signal detector / transmitter circuit 101 and the diode D11, so that a high impedance signal is sent to the ring terminal R, which is connected to the transformer T2! the main scene frall line. During the DID function sequence, this is a circuit for sending a number receiving signal to the main exchange, when the private, automatic side branch system receives all digits 35 from the main exchange system via the main exchange line and the DIOD main line circuit 90, or receives an unwanted number or an unauthorized number, and accordingly no more digital information is needed.

6 GB 176293 B1 Before the high impedance signal transmission mode, the relay drive circuit 107 is driven to the called state, a selector switch SW1 for high / low impedance transmission is positioned in the position 2 in order to form an impedance circuit. This state means that the CPU 10 is in a DTMF signal detecting state during the control of the DTMF receiving circuit 70.

When it is no longer necessary for CPU 10 to receive the DTMF signal, the high / low impedance transmission selector switch SW1 is positioned in position 1 by cutting off the relay drive circuit 107. Accordingly, a high impedance loop is formed by the resistor R1 and the diode D1, transmitting a high impedance signal to the main centerline.

10

This signal is maintained until the corresponding local subscriber 120 hears ring generating tones from the ring generator circuit 130 and lifts the tube, as shown in FIG. At this time, a callback tone supplied from the tone generator circuit 60 passes the voice circuit 102 in the DIOD main line circuit 90 via the switch circuit 50 which is connected to the voice path and is then converted in the transformers T1 and T2 and sent to the main central line. The transmission conditions for the high / low impedance signal in the DIOD signal detector / transmitter circuit 101 are described in detail.

The current flowing in the current limiter circuit 121 is limited through the diode D24 and the resistor R12 according to the position 1 or 2 of the high / low impedance transmission selector switch SW1. And the limited current is sent via the diode D11 and the terminal 1 to the bushing terminal T on the main central line. At this point, the current is less than about 3mA, which is observed in the main central system. Accordingly, charging is started and the central exchange system connects the voice path. This high impedance mode is a callback transmission mode, and when this signal is normally established, the telephone call is started.

When there is an incoming signal to the DIOD main line circuit 90 or the private automatic sideline telephone exchange system, the DIOD main line circuit 90 intercepts for outgoing signal, the low impedance signal forms a voice path and when a supply current source supplied via the main central line flows through the DIOD 90 main line , it becomes a low-impedance state.

Referring to Fig. 3, when the state of the high / low impedance signal transmitting selector switch SW1 is in position 2 at the excitation of the coil L1 connected to the relay drive circuit 107, the current flowing in the current limiter circuit 121 via the diode D24 becomes the photocoupler PT2 and the terminal 3, limited to 30 mA. The current, which is constrained in the current limiter circuit 121, passes the transformer T2 via the diode D11 and sends a low impedance to 7 DK 176293 B1 stop signal! to the call terminal R on the main exchange line. And, unlike the above transmission, the low impedance, polarity inverting signal is converted in the transformer T1 via the socket terminal T and is input to the terminal 4 in the DIOD detector / transmitter circuit 101 via the position 2 of the switch SW1, whereby it is passed through the photocoupler PT2 via 5 diodes D24. The signal which passes the photocoupler PT2 is current limited in s limiting the r-circuit 121 via the terminal 3 and passes the terminal 2 and is converted in the transformer T2 via the diode D11.

The signal which passes through the transformer T2 supplies current ten! the call terminal R on the main central line. The emitter state of each phototransistor is inverted in the inputs N11 and N12 via the resistors R14 and R15 according to the drive of the photocouplers PT1 and PT2. accordingly, a reverse battery signal is sensed at the terminal 10, and a forward battery signal is sensed at the terminal 11. When the two signals are received, and if any of them is in the "low" state, the AND gate AN11 output fe "low "mode, whereby a recording signal is generated! in AND gate AN 12. That we! say, it is generated regardless of the output of the AND gate AN 13, which is generated from the state of the printed circuit board protecting terminal 13 and the signal which is passed through the inverter N15.

After a low impedance signal is sent via the main exchange line, as described above, and the beehive felt in the main exchange system, then the exchange exchange system will connect the voice path.

With respect to the voice path connection and regardless of the state of the loop setting, only the time switch will be turned on / off in the switch circuit 50, activating the tone and DTMF transmission / detection. The tone signal detecting / transmitting circuit 104 of Fig. 3 performs the function 25 of the DTMF transmitting / receiving circuits 70 and 80 as well as the tone delivery circuit 60.

As described above, a DIOD main line function is provided, which enables throughput. Furthermore, there are advantages in terms of easy interfacing with the usual main center system, which improves reliability and makes installation work easy.

30

Claims (5)

8 DK 176293 B1 A through selection circuit having a direct inward / outward (DIOD) main line circuit (90) and an interface element (30) for use in an electronic, private sideline telephone exchange system, and wherein said DIOD main line circuit communicates with a switch circuit element. (50) and can be connected to socket (T) and ring (R) terminals to and from a main exchange line (co), and wherein said interface element can be connected between said DIOD main line circuit and a central processing unit (10) in said sideline telephone exchange system, and wherein said throughput system is characterized in that said DIOD main line circuit 10 comprises: one or more transformers (T1, T2) connected to said main central line; voice path element (102) connected between said transformers and said switch circuit element (50); high-impedance detecting element (101) connected to receive a high-impedance signal supplied from said main central line via said bushing and ring terminals, in order to supply the high-impedance signal to said interface element (30); a switch (SWi) which can be connected to said transformers for making a choice between either high-impedance or low-impedance signal transmission; 20 a relay driver element (107) which controls the switching function of said switch (SW1); elements (R1, D1) connected to said switch for generating the high-impedance and low-impedance signals, respectively; and a tone signal detecting and transmitting element (104) coupled between said voice path element (102) and said interface element (30), for detecting a tone signal! and sending the detected tone signal ten! said switch circuit element (50). The selection circuit according to claim 1, characterized in that said interface element further comprises a plurality of latch elements (105, 106, 108) for latching data corresponding to ten! said respective high and low impedance signals and to said detected tone signal, a control circuit (109) for controlling said drive drive element and generating a control signal for controlling said DIOD main line circuit (90), and a buffer circuit (110) for buffering of control data to be sent between said DIOD mainline circuit (90) and said central processor unit (10). 35 Selection circuit according to claim 1, characterized in that said high impedance detecting element comprises detecting elements for detecting an inverted state on the bushing and ring terminals on said main central line as well as conversion elements for amplifying the detected signal from said detecting element. in order to convert said detected signal to a high impedance signal. The selection circuit according to claim 3, characterized in that said detecting element further comprises power supply elements for generating a reference voltage from an output level of said detecting signal. The selection circuit according to claim 3, characterized in that said converting element further comprises a photocoupler for transmitting said detecting signal, Pass-through circuit according to claim 1, characterized in further comprising a current limiting circuit coupled between said transformers and high / low impedance signal generating elements for limiting current flowing in a loop. Pass-through circuit according to claim 6, characterized in that said current limiting circuit comprises photocouplers for transmitting current, as well as backward / forward battery signal generating elements for converting output from said photocouplers for generating backward / forward battery signals. The selection circuit according to claim 7, characterized by further comprising a busy signal generating element for generating a busy signal from output of said backward / forward battery signal generating elements by means of a printed circuit board protecting terminal. DK 176293 B1 o ° o V OG o rs — i r4 ~ l I ΐ si φ S; 2 '2 cQ (' S 'd ω 3 d ^ ^ upg ί yfi £ 2 £ o zy ^ u> fc ω? * F- * -r- K) * II JL ji or J «g U) Λ— o 1: 3 "/ - ~ N ^ *, 3 if) ~ -g * \ - / J *? S« υ ζκ £ ot y 0. I- Ί -Γ ---- 1 - V ^ - ~ | _ 0 tf 2 S- 3 o_ $ O If 3_I S3 _ "Φ ® CD ^ Χα <« / * / i / 3 1 ~ P 2. id j «ul cD, 5 tf o 0 C * <æ * - r ^ r ~ pø tt) * ______________________________________ * d ^ ip ^ oo tj K) DK 176293 B1 ooo σ ο- ϋ cd" "'- _ lu i K) j ~ ^ JL o_ £ Ο-p Or £ P ^ Lér Por C \ J - \ - PfeeNA>) C,% E, ^ h £ '"“ "I SL ^ fe:> oi 7 ίχ 05 PiXjE «. Poft "- \ - BA <; u5C ^ eHhe - ~ 'SUj & jRT_ ° o i-II-1 I ............. ~ ............. .......... ~ k.eei> SLf! R Til '--— FRehaRt Ks g.cva E —i—. 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