JP2964500B2 - Automatic trunk - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an automatic trunk of an exchange.

[Conventional technology]

FIG. 2 shows an example of a conventional automatic trunk. The communication path of the automatic trunk 26 is connected to the network 3. The peripheral control device 23 connected to the central control device 4 of the exchange,
The automatic trunk 26 is controlled via the control bus 24. When the automatic trunk 26 is not used, the idle channel signal from the idle channel signal generation circuit (IDLP) 5 is supplied to the automatic trunk 26 and terminated at the terminal (T) 21.

The subscriber 1 connected to the subscriber circuit 2 is connected to the automatic trunk 26.
Is dialed, the central control unit 4 of the exchange controls the network 3, disconnects the idle channel signal generation circuit 5 from the automatic trunk 26, and connects the path between the subscriber 1 and the automatic trunk 26. The central controller 4 sends a start command to the automatic trunk 26 via the peripheral controller 23.
When the signal transmission / reception circuit (SRD) 22 of the automatic trunk 26 receives the activation command, the signal generation circuit (TNG1) 9b is activated, and the signal of the automatic trunk 26 is transmitted to the subscriber 1.

[Problems to be solved by the invention]

The conventional automatic trunk described above has a drawback that it does not operate unless a start command is received through a peripheral control device.
It was not completely automatic.

An object of the present invention is to provide an automatic trunk which automatically performs a corresponding output operation based on a signal designating an operation type from a communication path of an exchange to reduce a processing load of the exchange such as control of a peripheral control device. Is to do.

[Means for solving the problem]

The automatic trunk according to the present invention comprises a signal identifying means for identifying a type of a signal input from a communication path of an exchange, and a predetermined communication path corresponding to the signal type identified by the signal identifying means. Operation selection executing means for executing an output operation for

〔Example〕

 Next, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing one embodiment of the present invention.
FIG. 1 (a) shows a case where the input signal to the automatic trunk is only one kind of idle channel signal. A subscriber circuit 2 to which a subscriber 1 is connected is housed in a network 3. The automatic trunk 6 is connected to the idle channel signal generator (IDLP) 5 via the network 3. The path of the network 3 is controlled by the central controller 4. The automatic trunk 6 is connected to the network 3 and detects an idle channel signal.
T) 7, an idle channel signal generation circuit (IDLP) 9a for generating an idle channel signal, a signal generation circuit (TNG1) 9b for generating a signal to be transmitted to the subscriber 1, and a signal detection state of the signal detection circuit 7. A selection circuit (SEL) 8 for selecting one of the idle channel signal generation circuit 9a and the signal generation circuit 9b based on the selection and connecting to the network 3 is provided.

 Next, the operation will be described.

When the signal detection circuit 7 detects the idle channel signal from the idle channel signal generation circuit 5, the automatic trunk 6 recognizes that the automatic trunk 6 is in an unused state. When the subscriber 1 dials the number of the automatic trunk 6, the central control unit 4 of the exchange controls the network 3 to control the idle channel signal generation circuit 5 and the automatic trunk 6.
Is opened to connect to the automatic trunk 6 of the subscriber 1.

While the signal detection circuit 7 of the automatic trunk 6 is detecting the idle channel signal, the selection circuit 8 selects the idle channel signal generation circuit 9a and the automatic trunk 6 transmits the idle channel signal. When the circuit 7 recognizes that the idle channel signal has stopped, the selection circuit 8 selects the signal generation circuit 9b, and the automatic trunk 6 automatically sends the output signal of the signal generation circuit 9b to the subscriber 1.

When the subscriber 1 is disconnected, the exchange again connects the idle channel signal generation circuit 5 to the automatic trunk 6, so that the signal detection circuit 7 detects the idle channel signal again, and the automatic trunk 6 transmits the signal of the signal generation circuit 9b. And the idle channel signal of the idle channel signal generation circuit 9a is transmitted.

FIG. 1B shows a case where the input signal of the automatic trunk is a plurality of multi-frequency signals. The difference between the configuration in this figure and the configuration in FIG. 1A is that the internal configuration of the automatic trunk 16 is different, and that the idle channel signal generation circuit 5 is controlled by the central control unit 4 in many cases. It is replaced by a multi-frequency signal transmission circuit (MFOS) 15 for transmitting a frequency signal, and other connections and configurations are the same. The automatic trunk 16 is connected to the network 3 and is a multi-frequency signal receiving circuit (MFREC) 17 for identifying the type of multi-frequency signal.
, An idle channel signal generation circuit (IDLP) 9a for generating an idle channel signal, signal generation circuits (TNG1, TNG2) 9b, 9c for generating signals having different frequencies and levels, and an announcement generation for outputting an announcement signal A circuit (ANM) 9d and one of the idle channel signal generation circuit 9a, the signal generation circuits 9b, 9b, and the announcement generation circuit 9d are selected based on the result of the signal type identification of the multi-frequency signal reception circuit 17, and the network is selected. Selection circuit (SE
L) 18 is provided.

When the multi-frequency signal transmission circuit 15 is connected to the automatic trunk 16 via the network 3 and a command signal designating the type of operation based on the multi-frequency signal is transmitted from the multi-frequency signal transmission circuit 15 to the automatic trunk 16, The multi-frequency signal receiving circuit 17 in 16 receives this command signal and identifies the type of operation specified. The selection circuit 18 selects one of the idle channel signal generation circuit 9a and the signal generation circuit, and 9b, 9b and the announcement generation circuit 9d based on the identification result of the multi-frequency signal reception circuit 17, and connects to the network 3. The selected circuit performs a predetermined operation, such as sending a signal to the network 3.

〔The invention's effect〕

As described above, the automatic trunk of the present invention includes signal identification means for identifying the type of signal input from the communication path, and responds based on the type of signal input along with the path setting of the communication path. Since the output operation for a predetermined communication path can be automatically performed, a peripheral control device is not required, and the burden of processing such as control of the peripheral control device by the central control device of the exchange can be reduced. .

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG. 2 is a block diagram showing an example of a conventional automatic trunk. 1 subscriber 2 subscriber circuit 3 network 4 central control unit 5 idle channel signal generation circuit (IDLP) 6,16,26 automatic trunk 7
Signal detection circuit (DET), 8,18 ... Selection circuit (SEL), 9a ...
… Idle channel signal generation circuit (IDLP), 9b, 9c ……
Signal generation circuits (TNG1, TNG2), 9d ... Announcement generation circuit (ANM), 15: Multi-frequency signal transmission circuit (MFO)
S), 17: Multi-frequency signal reception circuit (MFREC), 21: Termination, 22: Signal transmission / reception circuit (SRD), 23: Peripheral control device, 24: Control bus.

Claims (1)

(57) [Claims] 1. A multi-frequency signal receiving circuit for identifying a type of a multi-frequency signal input from a communication channel of an exchange, an idle channel signal generating circuit for generating an idle channel signal, and a signal having a different frequency and level. A signal generating circuit for generating an announcement signal; an announcement generating circuit for outputting an announcement signal; an idle channel signal generating circuit based on a signal type of the multi-frequency signal identified by the multi-frequency signal receiving circuit; and a signal generating circuit. And an operation selection executing means for selecting any one of the announcement generating circuits and executing an output operation for the corresponding predetermined communication path.