FI96653C - Method and apparatus for controlling circuit 109 in a digital multi-station network - Google Patents

Description

96653

The present invention relates to a multipoint network to which a master device and a plurality of slaves are connected using a rate matching according to CCITT standard V.110 and in which signals from different network terminals are combined by a combining device performing an AND operation.

In traditional and analog data networks using frequency division technology 10, the only way to transmit data is to use a modem through which the data terminal connects to the data network. In a modem, data signals are converted into audio-frequency signals that are transmitted over a network like speech signals. The more efficient data transmission used in digital networks, on the other hand, is based on the direct digital transmission of data signals without conversion to audio frequency signals. In today's data networks, synchronous or asynchronous data coming from different terminals and at different speeds is routed to a Data Interface Unit, which 20 adapts data of different speeds to a 2 Mbit / s link. The different rates are adjusted so that when the incoming data rate is low, the data fills only a portion of the 64 kbit / s slot capacity, and when the rate is high, the data uses multiple time slots. When using data adapter units 25 in the network together with digital branching and cross-connection devices, it is possible to branch and separate signals from the 2 Mbit / s link signal and equally to introduce new signals to this link. Less than 64 kbit / s Synchronous signals and asynchronous signals are adapted to a digital network using CCITT Recommendation V.110 "Support Port of Data Terminal Equipments with v-series type inter faces by an Integrated Digital Services Network".

CCITT Recommendation V.24 on data transmission in analogue networks defines the functional interface between the terminal and the modem. Recommendation 2 96653 defines the so-called 100 series interface circuits and their functional descriptions. The interface circuits include control and monitoring circuits 105, 106 and 109, which are responsible for controlling and monitoring the functions of the modems and main 5 devices required for data transmission. The operation of the circuits will now be briefly described. In device A, when circuit 105 (Request to send, RTS) is in the OFF state, the modem does not transmit a carrier, and when the circuit enters the ON state, the modem begins to transmit a carrier. In circuit 106 (Clear to send, CTS), the modem tells device 10 le A the status of its transmitter. The OFF state indicates that the modem is unable to transmit data, and the ON state indicates that the modem is capable of sending data to the line. After the circuit 105 of the circuit 105 is NOT -> ON, it takes a certain time for the circuit 106 to change to the ON state. During this time, the opposite modem 15 synchronizes its receiver and tells circuit 109 (DCD) that it is able to receive data from the line.

Recommendation V.110 defines the operation of circuits 105, 106 and 109 in a digital network. The frame rate used in the bit rate version is 80 bits. The frame is shown in the table in Figure 20. The frame comprises 10 octets numbered 0, .., 9. The eighth bit S and X of some octets are status bits and the D bits are data bits. The S and X bits are used to transmit channel control information. The use of bits is illustrated in the table in Figure 2. The S bits are grouped into two groups SA and SB to convey the mutual state of the two circuits. With the SB bits 105, the circuit is described as a circuit 109, and the X-bit is used to shift the frame synchronization state of the receiver to the state of the opposite circuit 106. When the S and X bits are zero, it corresponds to the state ON and the first bits correspond to the state OFF-30. In local data flow control e.g.

• from a computer (data terminal) to a baseband modem

(network terminal) the above circuits are used as follows: In standby mode, the network terminal sends the following status to the terminal: circuit 106 OFF, circuit 109 OFF. If the data terminal 35 wants to send characters, it sets the circuit 105 to ON

tl 3 96653 (request to send). It can start transmission only if it receives the status of circuit 106 from the network terminal such as the modem. During the state change, the network terminal transmits a synchronization pattern # in the frame where the status bits S are ones, i.e. 5 OFF. Once the receiving device is synchronized, it causes the status bits at the transmitting end to change to zero, i.e. to the ON state, and the transmission can begin. During data transfer, circuit 109 is also in the ON state. Disconnection takes place by setting the status bits S from zero (= state ON) to one 10 (= state OFF) and circuit 106 to OFF. The device # with which the communication has taken place # detects from the status bits of the received frame # that S = OFF and in turn sets its own circuit 109 to OFF.

The rate 15 density matching described above and the operation of circuits 105 # 106 # 109 are for point-to-point connections. Operation is complicated in a multipoint network # because the V.110 recommendation does not recognize multipoint usage. In a multipoint network, one master terminal communicates with several slave terminals.

20 Terminals can be computers or other devices that send and receive data. Such a network is shown schematically reduced in Figure 3. In it, the network comprising the parts inside the solid line comprises multiplexers 1, 2 and 9, branch links 5 # of the cross-connect device 5 # and network terminals 3 # 6 and 11. any communication device # that uses V.110 recommended rate matching and communication with circuits 105 # 106 and 109. The network terminal 11 is a baseband modem in Figure 30. Multiplexer 2 can also be viewed. . as a network terminal # because it is a communication device # where rate matching and said communication are performed in a V.110 unit connected to a multiplexer. From the multiplexer 1, the V1010 unit is separated into a separate network terminal 35 3. The terminals and are connected to the network via a network terminal and 4,965,63 data matching units. When the network terminal is a baseband modem, it and the master or slave terminal connected to it can be connected to a multiplexer or cross-connect field device with a standard pair cable up to a few kilometers away. The portion of the signal path in which V.110 frames are transmitted is shown by a dashed line.

The data sent by the master terminal 7 is routed to all slaves. The data sent by the slaves is partly routed along a common route to the master-10 terminal. Since not all slaves can transmit at the same time, alternation must be used. In it, the master terminal sends polls to the slaves about their willingness to send. The network does not take a position on the inter-device interrogation protocol, but the devices must be able to easily communicate with the transmission network. The communication of the slave devices and the master devices with the network is therefore very simple and largely follows the communication described above in circuits 105, 106 and 109. The device in question indicates its transmission desire on circuit 105 (RST), which the network acknowledges on circuit 106. the status of circuit 105 to circuit 109 of the master device.

The problem is how to transmit the status of the circuit 105 to the circuit of the master device, i.e. 105-109 signaling over the connection.

The branching performed by the cross-connect device in the deep network is preferably done by combining the data of the slave branches with a simple AND operation. Although the implementation is simple, the disadvantage is that it does not favor the use of rate matching or 105-109 signaling between the master and 30 slaves. An important feature of the V.110 procedure is the ability to transmit 105-109 signaling over the connection as shown for the S bits in Figures 1 and 2, but the AND operation overrides this feature because it requires the network terminal or the like to interrupt 35 V.110 frames. transmission, which adversely affects il 5 96653 circuit 109.

Therefore, most prior art network terminals do not perform any 105-109 transmission, with the master interface circuit 109 being fixedly ON. In some network terminals that perform V.110 rate matching, the 105-109 signal transmission is implemented with ASICs and special software. The disadvantage is that the commercially available ASIC must have a suitable interrupt signal and, secondly, the software 10 becomes very time-critical, which makes it difficult to implement the software.

It is an object of the present invention to provide a method which, without separate time-critical programs but using ASICs according to the V.110 recommendation, transmits the status information of the circuit 105 of the slave device to the master device as the status information of the circuit 109 in a multipoint network.

The method according to the invention is characterized by what is stated in claim 1. The telecommunication device implementing the method 20 is defined in claims 5 and 6.

In the network terminal Slave 105 according to the invention, the signal controls the network terminal in a known manner. In the slave network terminal, the data of the 105 circuit ti-25 going to its V.110 unit is forcibly controlled to the OFF state, and in the master network terminal, the state of the 109 circuit coming from the V.110 unit is inverted. In the unit of the slave network terminal V.110, the state of the circuit 105 is transferred to the SB bit of the frame to be transmitted, and in the master network terminal, the SB bit of the frame controls the circuit 109.

30 When the master network terminal searches for synchronization with its mass. the state of the 109 circuit visible to the ter device is known to be ON and after synchronization the state is the state of the SB. Since the state is inverted according to the invention, the actual state 109 must be applied to the master either OFF or ON. Thus, the state 109 to master 35 is always the same as the state of the Slave 105 signal.

i 6 96653

The invention will now be described in more detail with reference to the accompanying figures, in which Figure 1 shows the structure of a frame according to the V.110 standard, Figure 2 shows the use of S and X bits, Figure 3 shows a multipoint network and Figure 4 schematically shows network terminals. Reference is further made to Figure 3. It is desired that the status information of the circuit 105 of the slave device 1 be transmitted via the network to the status information of the master device 109, i.e. that the 109 going to the master monitors the status 105 from the slave.

Reference is made to Figure 4. The part between the dashed lines A, B describes a fixed point multipoint network. The signals from the different slave devices are combined in the member 47 performing the AND operation 15. The circuit 105 of the slave 46 is denoted in the figure as S105. This circuit S105 controls the transmission in a known manner, whereby the network terminal 44 associated with the slave 46 transmits TX frames according to V.110 and shown in Fig. 1 to the network during the transmission shift, and when there is no transmission shift, continuous one data is transmitted instead of frames, i.e. TX = 1. According to the invention, the circuit 105 going to block V.110 of the Slaven device 44 is forcibly controlled in block 45 permanently to the OFF state. When said V.110 block is set to transmit 105-109 status information according to the recommendations «

·. 25 (Fig. 2), it means that the SB of the frame to be transmitted

the bits are forcibly permanently ones, i.e. OFF. The network terminal 44 always sets the circuit state 105 to OFF in the network, regardless of the state of the slave device S105. According to the invention, an inverter 43 is added to the network terminal 42 of the master device 41, which inverts the state V109 coming out of the block V.110 of the network terminal. Thus, the state V109 obtained according to the recommendations is inverted to state M109, which is then passed to the master device. The above arrangements of the invention cause the M109 to monitor the state of the S105 independently of the networking operation performed in the network in the AND member 46.

II

7 96653

The operation of network terminals in different modes is described below:

Let us first consider the situation when slave 46 is not transmitting, where S105 = OFF. It follows that the network terminal 5 does not send frames to the network, where TX = 1. The network terminal 42 of the master 41 is not synchronized, so the state of the V109 circuit coming out of the V.110 block is ON according to the CCITT recommendation. However, this is inverted in the inverter 43, so that the state 10 M109 of the circuit 109 to be provided to the master device 41 is OFF. The circuit of the master M109 is thus in the same state as the circuit of the circuit of the slave device S105.

When the slave terminal 46 is in the transmission shift, its circuit S105 is in the ON (request to send) state. In this case, frames are sent to the network from the network terminal 44. According to the invention, the member 45 forcibly controls the state of the circuit 105 visible on the block V.110 of the network terminal 44 permanently to the state OFF. This causes the SB bits transmitted with the frame to the master according to the recommendation to be one, i.e. SB = OFF. After synchronizing the master network terminal 42 with the incoming frames 20, it detects that the state of the SB bits is OFF, whereby the state of the circuit V109 provided by the block of the network terminal V.110 is OFF according to the SB bits. According to the invention, this is inverted in the inverter 43, whereby the state M109 of the circuit 109 actually given to the master by the network terminal is ON. The circuit of the master 25 M109 is thus in the same state as the circuit of the slave device S105.

When the transmission of Slave 44 ends, the circuit S105 visible to its network terminal changes to OFF, which directs network terminal 44 to cut off the transmission of frames to the network, where TX = 1. Master network terminal events are divided into two parts: 1) Master network terminal does not lose frame lock immediately but receives one bit and thinks therefore, the SB bits of the frame are still ones, i.e. denote the OFF state of the received circuit 105, whereby the state of the circuit VI09 given by the block V.110 of the network terminal 8 is still OFF according to the SB bits. When the belief of the master terminal is inverted according to the invention, the terminal 42 gives the master 41 a state of ON as the state of the circuit M109.

5 2) When the master network terminal loses the frame lock after a while, its V109 circuit status changes to ON according to the CCITT recommendation. This state is inverted in the inverter 43, whereby the master is given the OFF state of the circuit M109. The circuit of the master M109 is thus in the same state 10 as the state of the circuit of the slave device S105. However, the state change of M110 follows the state change of S109 with a small delay, which is the time of losing the frame lock.

As described above, hardware arrangements are added around the network terminals of both the master and the slave device, by which the signal 105 going to the circuit of the slave network terminal V.110 is forcibly controlled to the OFF state and the state 109 provided by the master network terminal is inverted. Otherwise, the network terminals will operate in accordance with Recommendation V.110. Thanks to the additions made, the units of the terminals V.110 20 transmit the recommended 105-109 status information over a network using the AND operation to combine the signals from the sla-ve devices.

It is to be understood that the above description and the accompanying figures are for illustrative purposes only. 25 to list the present invention. Various variations and modifications of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention as set forth in the appended claims.

Claims (6)

A method for transmitting information about the state of a slave terminal 105 circuit as information about the state of a 109 circuit to a master terminal of a multi-point network to which the master terminal and the slave terminal have been connected by a siulan data communication device which utilizes speed adaptation and communication in accordance with CCITT Recommendation V.110, including circuits 105, 106 and 109, and in which multipoint networks signals coming from different data communication devices are joined by a combiner (47), which performs an AND operation, and the data communication device at the slave end transmits a V. 10O frame only where the slave terminal 105 circuit is in 0N state, and otherwise it transmits '1' bits, the data communication device at the master end is without frame reading, in accordance with V. 110 recommendation ON as state information on the 109 circuit, characterized in that in the data communication device (44) in the slave end is forced the 105 circuit in the OFF state independent of the state of the slave terminal (46) 105 circuit, whereby state information OFF of the data communication device (44) 105 circuit of the slave terminal is transmitted to the SB bit of the frame to be transmitted; that the state of the 109 circuit, which is delivered by the data communication device (42) at the master end, is inverted before it is transmitted to the master terminal (41). 30 A method according to claim 1, characterized in that dk state information (S105) about the 105 circuit of the slave terminal (46) is OFF, the data communication device (44) at the slave end not transmitting the V. 10O frame and the data communication device (42). at the mast end is not read-read, state information ON, which is delivered by the data communication device (42) at the master end, is inverted to the OFF state and is routed to the master terminal (41) as state information (M109) of the 109 circuit. The stop information (S105) on the 105 circuit of the slave terminal (46) and the 109 circuit state information (M109) to be routed to the master terminal are identical. Method according to claim 1, characterized in that the state information (S105) of the slave terminal (46) 105 circuit is ON, whereby the data communication device (44) transmits at the slave end a V.110 frame, reads the data communication device (42). ) at the master end of the SB bit in the frames it received, OFF as state information and sets OFF as state information of its 109 circuit, said state information OFF of the 109 circuit is inverted to an ON state and is routed to the master terminal (41 ) as state information (M109) about the 109 circuit, where the state information (S105) about the slave terminal 105 circuit and the 109 circuit state information (M109) to be routed to the master terminal are identical. 4. A method according to claim 1, characterized in that the di-slave terminal (46) terminates the transmission, the state information (S105) of its 105 circuit is changed to OFF state, whereby the data communication device (44) in the slave end does not transmit a frame. , the data communication device (42) at the master end 30 gets rid of the frame listing and sets ON as its 109 circuit state information, the state information ON if the 109 circuit is inverted to OFF state and is routed to the master terminal (41) as the 109 circuit state information (M109) , wherein the state information (S105) on the 105 circuit of the slave terminal (46) 96653 14 and the 109 circuit state data (M109) to be fed to the master terminal are identical. 5. A data communication device which connects the slave terminal (46) to a multi-point network using speed adaptation and communication in accordance with CCITT Recommendation V.110 by means of circuits 105, 106 and 109, and in which multi-point networks signals coming from different branches , is joined by a combination device (47) which performs an AND operation before being passed to the data communication device (42) at the master end, characterized in that the data communication device has a forcing means (45) which permanently forces the 105 communication circuit in OFF state, wherein the SB bit, which states the state of the 105 communication circuit, in the frame departing from the data communication device is permanently in the OFF state, and the 105 circuit of the slave terminal is in the 0N state. 6. A data communication device which connects a master terminal (41) to a multipoint network by employing speed adapters and communications in accordance with CCITT Recommendation V.110 by means of circuits 105, 106 and 109, and in which multipoint networks signals coming from different branches from the slave data communication device are joined by a combining device (47) which performs an AND operation before being passed to the data communication device, characterized in that the device has an inverter means (43) to which the state information of the input 109 communication circuit is given a circuit operating according to the recommendation is conducted, the state information (M109) obtained from the output of the inverter (43) and which is opposite to the input is the state information of the 109 communication circuit to be provided to the master device (41 ), wherein the interface of the data communication device at the multipoint network il 96653 page is operatively connected to the output of such a slave data communication device (44), in which the SB bit to be transmitted has been forced in the OFF state, the output not transmitting a frame dk the slave terminal 105 circuit 5 in the OFF state. to ignition.