JPH0511694B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a digital transmission system for pair cables,
In particular, the present invention relates to a digital transmission system for pair cables for transmitting digital signals in ternary code format using pair cables.

[Conventional technology]

BACKGROUND OF THE INVENTION With the progress of digitization of transmission systems in public communication networks and the like, digital transmission systems for pair cables, which transmit digital signals using pair cables, are being put into practical use. The conventional digital transmission method for pair cables mainly uses a pulse code modulation (PCM) signal in a frame structure with a predetermined format, so that pulses of positive and negative polarity appear alternately (AMI).
It is transmitted in AMI code format. During communication, first a frame containing a training signal for training the equalizer for waveform distortion equalization provided in the receiving section of the termination device of the pair cable is transferred, and the equalizer is trained and frame synchronization is established. After execution, transfer to communication between end devices.

[Problem that the invention seeks to solve]

On the other hand, in a pair of cables constituting a communication line, the so-called chip side and ring side wire pairs are not necessarily connected correctly without reversal between both ends. Therefore, the pulse polarity of the digital signal transmitted from one of the two terminal devices connected via the pair cable during communication may be reversed when the other terminal receives it. The conventional transmission method mentioned above uses the AMI code format,
The pulse polarity itself can be completely ignored during decoding, and communication is possible regardless of whether or not the pulse polarity is reversed as described above.

However, in order to improve transmission efficiency, 3B2T and
When using a ternary code format such as 4B3T, if the pulse polarity of a digital signal obtained by ternary encoding a binary word is reversed, the word cannot be decoded into the original binary word. Therefore, in this case, decoding that ignores pulse polarity is impossible, and conventional transmission methods cannot be used for communication lines that include paired cables in which the chip side and ring side are connected without inversion at both ends. The problem is that it is impossible to apply it as is.

SUMMARY OF THE INVENTION An object of the present invention is to provide a digital transmission system for pair cables that solves the above-mentioned problems and allows correct decoding regardless of the presence or absence of pulse polarity reversal in the transmission medium.

[Means for solving problems]

The transmission method of the present invention receives a ternary digital signal having a frame configuration in which a predetermined frame pattern is inserted and containing pulses of positive and negative polarity arriving via a transmission path with a pair of cables. first and second discriminators that identify the presence or absence of the positive polarity pulse and the negative polarity pulse, respectively; and the frame pattern and the pulse of the frame pattern in the transmission signals of the first and second discriminator, respectively. first and second frame synchronization circuits that establish frame synchronization by detecting the timing at which a pattern with inverted polarity appears, and depending on which of the first and second frame synchronization circuits the frame synchronization is established; a switching controller that generates a control signal indicating the presence or absence of polarity reversal in the transmission path; and a switching controller that does not switch the output signals of the first and second discriminators with each other when the control signal indicates that the polarity is not reversed. a polarity switcher that switches the connection state so that the output signals of the first and second discriminators are exchanged with each other and then guided to the decoder when the control signal indicates that the polarity is inverted; The receiver is equipped with the following.

〔Example〕

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

FIG. 1 is a block diagram showing one embodiment of the present invention. In this embodiment, a polarity switch 5 for switching the pulse polarity and a switching controller 9 for controlling this switching are newly added to the reception section of the terminal device that transmits and receives digital signals in the ternary code format. It has a configuration set up in . The cable 10 is a pair cable and is connected to the line interface 1 of the termination device. The line interface 1 is equipped with a circuit, such as a time division switch or a hybrid circuit with an echo canceller, for preventing the digital signal transmitted from the transmitting section to the cable 10 from going back to the receiving section. A received signal that has arrived via the cable 10 from the terminating device on the other side passes through the line interface 1 and is then guided to the receiving section. The equalizer 2 in the receiving section is provided to equalize waveform distortion generated in the transmission path, and operates adaptively in response to a training signal in a training frame sent from the other party at the start of communication. , when the training operation converges, generates a convergence display signal and sends it to the switching controller 9, and sends the received signal whose waveform has been equalized to the discriminators 3 and 4. Discriminators 3 and 4
identify a positive polarity pulse and a negative polarity pulse in the received signal given from the equalizer 2, generate a pulse with a predetermined pulse width at the time of identification, and send it to the polarity switch 5 and the frame synchronization circuits 7 and 8. send. Frame synchronization circuits 7 and 8 are ternary frame synchronization circuits. The frame pattern transmitted from the other party has a pulse pattern in a predetermined three-value format, and the frame synchronization circuit 7 uses the discriminator 3
Frame synchronization is established by detecting the timing at which the above-mentioned frame pattern appears in the positive and negative pulse trains sent from 4 and 4, respectively. The other frame synchronization circuit 8 establishes frame synchronization by detecting the timing at which a pattern in which the pulse polarity of the above frame pattern is inverted appears in the pulse train sent from the discriminators 3 and 4. That is, if there is no pulse polarity reversal in the transmitter including the cable 10, frame synchronization is established in the frame synchronization circuit 7, and if there is pulse polarity reversal in the transmission path, the frame synchronization circuit 8 establishes frame synchronization.
Frame synchronization is established at Of the frame synchronization circuits 7 and 8, the one in which frame synchronization has been established generates a pulse to indicate the establishment of synchronization and sends it to the switching controller 9. After the equalizer 2 converges, the control switch 9 inverts the pulse polarity in the transmission line including the cable 10 depending on which of the frame synchronization circuits 7 and 8 the pulse indicating the establishment of synchronization comes from. If there is no inversion (or if there is), the output pulse train of the discriminator 3 (or 4) is guided to the positive pulse input terminal of the decoder 6, and the output pulse train of the discriminator 4 (or 3) is detected. The connection state of the polarity switch 5 is set so that the output pulse train is guided to the negative pulse input terminal of the decoder 6.

In this way, during the training period, training of the equalizer 2 and establishment of frame synchronization are executed, and at the same time, pulse polarity reversal on the transmission path is detected, and if there is reversal, the polarity switch 5 re-inverts the pulse polarity. Therefore, when transitioning to subsequent communication, the decoder 6 performs normal decoding and outputs received data regardless of whether or not the pulse polarity of the transmission path is reversed.

FIGS. 2a and 2b are a block diagram showing an example of the configuration of the polarity switch 5 and the switching controller 9 in this embodiment, and a timing diagram for explaining the operation thereof, respectively. Figure b shows that the frame pattern of the transmission signal from the other party is {+1, 0, 0, -1,
0, 0}, and the pulse is received via a transmission path with the polarity reversed. The frame synchronization circuit 7 detects the appearance timing of the frame pattern, and the frame synchronization circuit 8 detects the appearance timing of the frame pattern by inverting the pulse polarity of the frame pattern {-1, 0,
0, +1, 0, 0}, synchronization is established, and the one that is able to establish synchronization sends out a pulse. The pulse indicating the establishment of synchronization is led to the data selector 90 of the switching controller 9 together with the convergence indicating signal of the equalizer 2. In addition to this, a high level (H) voltage and a low level (L) voltage are applied to the data selector 90 as input data. During the pulse rising period of the convergence display signal of the equalizer 2, the data selector 90 selects an H voltage when receiving a pulse from the frame synchronization circuit 7, and selects an L voltage when receiving a pulse from the frame synchronization circuit 8. and send it. In the example shown in Figure b, the received signal undergoes pulse polarity inversion on the transmission path, so
The frame synchronization circuit 8 establishes synchronization and sends out pulses. In response, data selector 90 sends out the L voltage. If there is no pulse polarity reversal on the transmission path, the frame synchronization circuit 7 establishes synchronization and sends out a pulse, and in response, the data selector 90 sends out an H voltage.
The output signal of the data selector 90 is transmitted to the polarity switch 5
switch SW ₁ , and inverter 50
The high and low levels are reversed and applied to switch SW ₂ . Both switch SW ₁ and SW ₂ are
It turns on when H voltage is applied, and it turns on when L voltage is applied.
It turns off when voltage is applied. Therefore,
If there is no pulse polarity reversal on the transmission path, switch SW ₁ is turned on, switch SW ₂ is turned off, and the output signals of discriminators 3 and 4 are sent to decoder 6 without being swapped. is connected to the positive polarity pulse input terminal and the negative polarity pulse input terminal of.
Also, if there is pulse polarity reversal in the transmission line,
The switch SW ₁ is turned off, the switch SW ₂ is turned on, and the output signals of the discriminators 3 and 4 are exchanged with each other and then connected to the decoder 6. As a result, the connection state of the polarity switch 5 is set so that a positive pulse train and a negative pulse train having the same pattern as the transmission signal are input to the positive pulse input terminal and the negative pulse input terminal of the decoder 6, respectively. and when transitioning to communication, the decoder 6
Normal decoding can be performed.

〔Effect of the invention〕

As described above, the present invention has the effect of realizing a digital transmission system for pair cables that allows correct decoding of ternary codes regardless of the presence or absence of pulse polarity inversion in the transmission path.

[Brief explanation of the drawing]

1 and 2a are block diagrams showing an embodiment of the present invention, and FIG. 2b is a timing diagram for explaining the operation of the embodiment of the present invention. 1...Line interface, 2...Equalizer,
3, 4... Discriminator, 5... Polarity switch, 6... Decoder, 7, 8... Frame synchronization circuit, 9... Switching controller, 10... Cable, SW ₁ , SW ₂ ... Switch , 50...inverter, 90... data selector.

Claims (1)

[Claims] 1. A ternary digital signal having a frame configuration in which a predetermined frame pattern is inserted and containing pulses of positive polarity and negative polarity arrives via a transmission path with a pair of cables, and detects the positive polarity and the negative polarity, respectively. first and second discriminators that identify the presence or absence of the negative polarity pulse; and the frame pattern and a pattern in which the pulse polarity of the frame pattern is inverted in the transmission signals of the first and second discriminators, respectively. first and second frame synchronization circuits that detect the appearing timing and establish frame synchronization; and polarity on the transmission path depending on which of the first and second frame synchronization circuits establishes the frame synchronization. a switching controller that generates a control signal indicating the presence or absence of polarity inversion, and a switching controller that guides the output signals of the first and second discriminators to a decoder without exchanging each other when the control signal indicates that the polarity is not inverted; a polarity switcher that switches the connection state so that when the control signal indicates that the polarity is inverted, the signals transmitted from the first and second discriminators are exchanged with each other and then guided to the decoder; A digital transmission method for pair cables that is characterized by: