JPS6325549B2 - - Google Patents

Description

[Detailed description of the invention]

The present invention converts a 1-bit code connection signal into a 2-bit code connection signal between exchanges and transmits PCM.
This relates to a signal conversion method for transmission by a device. An E/M signal system is known in which an E signal and an M signal are used as connection signals for exchanges, and are transmitted between exchanges as a 1-bit code by a PCM device.
On the other hand, the R2 signaling system of CCITT Recommendation Q421 is defined to transmit connection signals using 2-bit codes. Therefore, with the existing E/M signaling system switch,
In a switching network that includes electronic exchanges to which the R2 signaling system can be applied, it is necessary to convert connection signals between 1-bit codes and 2-bit codes. An object of the present invention is to convert the connection signal of the above-mentioned exchange with a simple configuration. Examples will be described in detail below. Figure 1 is a block diagram of the main parts for transmitting connection signals between existing exchanges using the E/M signaling system.
The exchanges 1 and 9 are connected by PCM devices 4 and 6 via PCM transmission lines 5a and 5b, and the trunks 10a to 10n of the exchange 1 are connected to the multiplexing unit 11 of the PCM device 4 by the M lead 2.
a to 10n are connected to the isolation portion 12 and the E lead 3. Similarly, between the exchange 9 and the PCM device 6, the trunks 15a to 15n and the multiplexing unit 14
and is connected to the separation section 13 by an M lead 8 and an E lead 7. For example, ground is sent as an M signal to the M leads 2 and 8 in response to a call and a response, and the multiplexer 1
1 and 14 and sent out to transmission lines 5a and 5b, separated by separation sections 12 and 13, and sent to the trunk by E leads 3 and 7. In this case, the data is transmitted using a 1-bit code. FIG. 2 is a block diagram of an embodiment of the present invention, in which the exchanges 21 and 29 use the E/M signal system, and the PCM devices 24 and 26 are equipped with a signal conversion circuit 3 for converting a 1-bit code into a 2-bit code.
1,34 are provided. Also, 22, 28 are M leads, 23, 27 are E leads, 30a to 30n, 3
5a to 35n are trunks, 25a and 25b are transmission lines, and 32 and 33 are demultiplexing units. Since the signal conversion circuits 31 and 34 convert the 1-bit code connection signal and the 2-bit code connection signal, it becomes possible to transmit the connection signal using the R2 signal system. Note that a double E/M signal system is also known, and in this case, since the M signal has a 2-bit configuration, the connection signal can be transmitted as a 2-bit configuration without signal conversion. FIG. 3 is a block diagram of another embodiment of the present invention, in which a connection signal is transmitted between an exchange 21 of E/M signaling system and an electronic exchange 36 of R2 signaling system. , the same symbols as in FIG. 2 indicate the same parts. Since the electronic exchange 36 uses a 2-bit code connection signal, the connection signal is transmitted by PCM multiplexing, and the exchange 21 uses a 1-bit code connection signal, so the signal conversion circuit 31 converts the 1-bit code and the 2-bit code. , thereby making it possible to transmit connection signals using the R2 signaling system according to the CCITT recommendations. FIG. 4 is an explanatory diagram of the interface conditions of the signal conversion circuit. Between the trunk 41 of the output side OG and the signal conversion circuit 44, there are
The trunk 48 of the input IC and the signal conversion circuit 45 are connected by an E lead 46 and an M lead 47. Also, signal conversion circuit 4
4 is converted into 2-bit code of af and bf and sent.
The signal conversion circuit 45 of the input side IC converts the signal into 2-bit codes of ab and bb and sends it out. FIG. 5 is a block diagram of main parts showing a specific example of the signal conversion circuits 44 and 45 shown in FIG. It is shown as a thing.
However, if the trunk is computerized, this M signal can of course be used as the output of a switching element or a logic circuit. Since the 2-bit code according to Q421 of the CCITT recommendation is specified in relation to the operating state, signal conversion is performed as shown in Table 1 in relation to the M lead and E lead. In addition, the exit side OG and the input side
In the M and E columns indicating the M lead and E lead of the IC, P indicates open, and G indicates ground. Also the fifth
In the figure, RL1 to RL4 are relays, rl1 to rl4
¹ , rl4 ² is the contact, G1 to G5 are the gate circuits,
INV1 to INV4 are inverters, V is power supply, ALM
1. ALM2 is a failure alarm section of the PCM device, and CHP is a channel pulse for multiplexing.

[Table] As can be seen from Table 1, the af of the exit side OG is M
It is “0” when the lead is ground G, “1” when it is open P, and bf is always “0” and “1” only when there is a failure.
shall be. Also, the E lead of the input IC is grounded G when af="0" and is open P when af="1" or bf="1". Normally, ab sent from the input IC is "1", but it is set to "0" only when af = "0" is received and the M lead of the input IC is at ground G. Also, bb is normally set to “1”, af=“1” is received, and M of the ingress IC is
Set to "0" when the read is open P. Matade side OG
When the E read of is sending af="1",
When bb="0" is received, it is set to open P, when bb="1" is received, it is set to ground G, and when ab="0" is received when af="0" is sent, ground G, ab
="1" is received, it is set as open P. Therefore, in the idle state, contact m1 is off and M
Since the lead 42 is open P, the inverter
The output of INV1 becomes "0" and relay RL1 does not operate. Note that the relays RL1 to RL4 operate when "1" is added to them. Gate circuits G1 and G2 have channel pulses for multiplexing.
CHP is applied, and when the output of the inverter INV1 is "0" and the channel pulse CHP is "1", the output of the gate circuit G1 becomes "1". That is, af="1". Also, failure alarm unit ALM
1. ALM2 outputs “1” due to fault detection,
If there is no fault, it outputs "0". Therefore, the output of the gate circuit G2 normally becomes "0" at the timing when the channel pulse CHP is "1".
That is, bf="0". This 2-bit code af,
bf is multiplexed by the demultiplexer and sent out. In the input IC, the 2-bit codes af and bf separated by the demultiplexer are applied to the signal conversion circuit 45, and as described above, since af="1" and bf="0", the output of the inverter INV3 is Since the output of gate circuit G3 is “0”, relay RL3,
RL4 doesn't work. Therefore, since the contact rl3 is off as shown, the E lead 46 becomes open P. In addition, in the idle state, the contact m2 is off and the M lead 47 is in the open P state, and the relay RL4 is in the non-operating state, so the contacts rl4 ¹ and rl4 ² are in the state shown, and the channel pulse CHP is "1". ”, the output of gate circuit G4 is “1”,
That is, ab="1", and the output of the gate circuit G5 becomes "0", that is, bb="0". These 2-bit codes ab and bb are multiplexed by a demultiplexer and sent out. At the output side OG, the 2-bit codes ab and bb separated by the demultiplexer are applied to a signal conversion circuit 44.
At this time, since the relay RL1 is in the non-operating state, the contact rl1 is in the illustrated state, and since bb="0", the relay RL2 is in the non-operating state, and the E lead 43 becomes open P. Therefore, in the idle state, as shown in Table 1, the M lead and E lead of the outgoing OG and incoming IC are open P, respectively, and the 2-bit code is af="1", bf="0" and ab ="1", bb="0"
becomes. In the startup state when a call is made from the outgoing OG, ground is sent from the trunk to the M lead.
This corresponds to contact m1 being turned on, whereby the output of inverter INV1 becomes "1" and relay RL1 operates. Further, at the timing when the channel pulse CHP is "1", the output of the gate circuit G1 becomes "0", that is, af="0". In the input side IC signal conversion circuit 45, an inverter
The output of INV3 becomes "1" and relay RL4 operates. Also, since bf = "0" and the output of the fault alarm unit ALM2 is "0", the output of the gate circuit G3 becomes "1", the relay RL3 operates, its contact rl3 turns on, and the E lead 46 becomes Earth G
becomes. At the time when the aforementioned 2-bit codes af and bf are received, the 2-bit codes ab and bf from the signal conversion circuit 45 are
bb has not changed, but as relay RL4 operates, contact rl4 ¹ turns on and contact rl4 ² turns off, so at the timing when channel pulse CHP is "1", the outputs of gate circuits G4 and G5 are "1", that is, ab="1" and bb="1", resulting in the startup confirmation state shown in Table 1. Since the called side responds by sending a ground to the M lead 47, this corresponds to the state where the contact m2 is on, so that the output of the AND circuit G4 becomes "0" at the timing of the channel pulse CHP, that is,
ab=“0”. Note that bb="1". In the output side OG signal conversion circuit 44, relay RL1 operates, and since ab="0", the inverter
The output of INV2 becomes "1", relay RL2 operates, and contact rl2 turns on, so E lead 43
becomes Earth G. That is, the response state shown in Table 1 is reached. Clearing back is when the incoming IC recovers first.
M lead 47 is open P, and the exit side
OG E lead 43 becomes open P. Also, in the case of a clear return, when the output side OG is restored first, the M lead 42 becomes open P, and the E lead 46 of the input side IC becomes open P. Restoration guard indicates a case where the line is restored to an idle state, and block indicates a blocked state of the line. It is of course possible to replace the relays RL1 to RL4 in the above embodiment with electronic switches, and the signal conversion operation by the gate circuits G1 to G5, etc.
It can be executed by channel-compatible time-division processing using a microprocessor. Further, in the embodiment shown in FIG. 5, relays RL1,
It is also possible to use RL4 as a slow recovery relay to prevent malfunction when noise is applied to M lead 42. That is, even if the ground G and open P of the M lead 42 change instantaneously, the relay RL1 maintains its previous state, so the 2-bit codes af and bf do not change. Also, when transmitting dial pulses by M lead 42, bit af is “1” and “0”.
However, by making relay RL4 of the incoming IC a slow recovery relay that operates from the call origination to the end of the call, like the B position relay, the 2-bit code
ab, bb will not change, and E lead 46
Dial pulses can be transferred from the trunk to the trunk. As explained above, the present invention provides a switching system including a switch using the E/M signaling system.
The connection signal can be transmitted using the 2-bit code R2 signal system, and the means for converting the 2-bit code corresponding to the relationship between the M lead and E lead is relatively simple, and the existing E/M signal system can be transmitted. Even in an exchange system in which an electronic exchange using the R2 signaling system and an electronic switching system using the R2 signaling system coexist, connection signals can be transmitted using the R2 signaling system.

[Brief explanation of drawings]

Figure 1 is an explanatory block diagram of connection signal transmission using the E/M signaling system, and Figure 2 is an embodiment of the present invention in which the connection signal is transmitted between exchangers using the E/M signaling system by converting it to the R2 signaling system. An explanatory block diagram to be transmitted,
FIG. 3 is an explanatory block diagram for transmitting connection signals using the R2 signaling system between an E/M signaling system exchange and an R2 signaling system exchange according to another embodiment of the present invention, and FIG. 4 is a signal conversion diagram. FIG. 5, which is an explanatory diagram of circuit interface conditions, is a block diagram of a signal conversion circuit according to an embodiment of the present invention. 1, 9, 21, 29 are E/M signaling type exchanges, 10a to 10n, 15a to 15n, 30a to
30n, 35a to 35n are trunks, 2, 8, 2
2, 28, 42, 47 are M leads, 3, 7, 2
3, 27, 43, 46 are E leads, 4, 6, 2
4, 26 are PCM devices, 31, 34, 44, 45
is a signal conversion circuit, 32 and 33 are demultiplexing units, and 36
is an R2 signaling electronic switch.

Claims (1)

[Claims] 1. In a switching system that uses the M signal and the E signal as connection signals for exchanges, and uses the Single E/M signal system that is transmitted between exchanges via a PCM device, the connection signal is converted into a 2-bit code.
This is a signal conversion system for transmission using the R2 signal system, and the bit af is set to "1" when the output M lead is open and "0" when it is grounded, and the bit af is always "0" and becomes "1" only in the event of a failure. means for converting into a 2-bit code with bit bf that is ”, and an E lead on the input side that receives the 2-bit code is grounded when the bit af is “0”, and when the bit af is “1” or the bit bf is A means for opening when it is “1”, and a bit ab that is always “1” and is “0” only when the bit af is “0” and the input side M lead is grounded.
This bit is always “1” and is “0” when the bit af is “1” and the input side M lead is open.
bb into a 2-bit code; and transmitting the bit af as "1";
When receiving "0" on bit bb, the output side E lead is opened, and when receiving bit bb "1", the output side E lead is grounded, and the bit af is sent as "0". And the bit ab is “0”
The signal conversion method is characterized in that the signal conversion method is characterized in that the signal conversion method is characterized in that the signal conversion system is characterized in that the signal conversion system is characterized in that the signal conversion system is characterized in that the signal conversion method is characterized in that the signal conversion method is provided with means for grounding the output side E lead when the bit AB is received, and opening the output side E lead when the bit AB is received as "1".