KR200169531Y1 - Channel multiplexer of adsl - Google Patents

Abstract

The present invention not only transmits the same control signal information as the existing use by multiplexing the low speed control channel, but also secures an information channel that can be utilized for multimedia and Internet services, thereby increasing the availability and utility of the communication line. A control channel multiplexing device for a line digital transmission device, comprising: a high speed converter (20a, 20b) for receiving 38.4 Kbps signals and 9.6 Kbps signals, which are low-speed asynchronous digital signals, and converting them into synchronous signals of 48 Kbps and 16 Kbps, respectively; A multiplexer 20 which receives the converted 48Kbps signal, 16Kbps signal, overhead signal and 1.544Mbps signal and selectively outputs the received 48Kbps signal according to a time division control signal; A frame arrangement unit 3 performing the same function as in the conventional asymmetric subscriber line digital transmission apparatus; A signal synthesis separator 5; Demodulation section 7; Frame reconstruction unit 8; Bit counter 11; A demultiplexer (90) for separating and outputting an overhead signal, a 48Kbps signal, and a 16Kbps signal from a high-speed data sequence extracted by the frame reconstruction unit (8) by a time division control signal; Low-speed converters 90a and 90b for converting the separated synchronous 48Kbps signal and 16Kbps signal into asynchronous 38.4Kbps signal and 9.6Kbps signal; And a control logic circuit 120 for outputting the time division control signal for separation of an image signal channel (1.544 Mbps) and a control channel (64 Kbps) as well as for multiple signal separation of a control channel. It is a very useful design that has the effect of eliminating the line waste and the cost of line installation by efficiently using the line by providing communication service such as internet service without multiple line installation by multiplexing the communication capacity.

Description

Control channel multiplexing device for asymmetric subscriber line digital transmitter

The present invention relates to a control channel multiplexing device of an asymmetric subscriber line digital transmitter having a different transmission speed according to a transmission direction, and more particularly, to select and control the content of a signal transmitted at high speed downward through a subscriber line. In addition to transmitting the same control signal information as the existing use by multiplexing low-speed control channels, an asymmetry that increases the availability and utility of communication lines by securing information channels that can utilize extra transmission capabilities for multimedia and Internet services. The present invention relates to a control channel multiplexing device for a subscriber line digital transmission device.

The conventional asymmetric subscriber line digital transmission apparatus is divided into the image information provider side (Fig. 1 (a) and the image information user side (Fig. 1 (b)), as shown in FIG. The apparatus includes: a multiplexer (2) which receives an overhead signal, a 1.544 Mbps image signal, and a 64Kbps control signal and sequentially transmits the received signal according to a time division control signal; asymmetrical subscription of the signal transmitted from the multiplexer (2) A frame arranging unit (3) for arranging and transmitting an Asymmetric Digital Subscriber Line (ADSL) signal frame and transmitting the same; a modulator (4) for modulating the transmitted signal by a carrierless amplitude phase (CAP) method; A signal synthesizing separator for synthesizing the signal and the voice signal input through the telephone 6 and transmitting it through the telephone line L, and separating the signal received through the telephone line L into an information signal and a voice signal ( 5) a demodulator 7 for demodulating and outputting the CAP modulated signal received through the signal synthesizing section 5 into an original signal; and additionally arranged a frame from the demodulated signal for stability and reliability of the signal. A demultiplexer 9 for distributing the output signal of the frame reconstructor 8 by a time division control signal; an output digital signal of the multiplexer 2 and the demultiplexer 9 And a bit counter 11 for counting the number of transmission bits of the input digital signal, and a control logic circuit 12 for generating and outputting the time division control signal on the basis of the counted number of bits.

In addition, the information user side apparatus of Fig. 1 (b) includes: a multiplexer 2 'which sequentially outputs an input overhead signal and a 64 Kbps signal according to a time division control signal; A demultiplexer 9 'for separately outputting an overhead signal, a 1.544Mbps signal and a 64Kbps signal to a corresponding signal line according to a time division control signal; and a frame arrangement unit performing the same operation as the components of FIG. 3); A modulator 4; A signal synthesis separator 5; Demodulation section 7; Frame reconstruction unit 8; Bit counter 11; And a control logic circuit 12.

In the conventional asymmetric subscriber line digital transmission apparatus configured as described above, when the apparatus at the image information provider side transmits information to the apparatus at the subscriber side, the multiplexer 2 first performs an overhead signal, a 1,544 Mbps signal, and From the overhead signal for the first transmission of the 64Kbps signal is sent to the frame arrangement unit (3). The bit counter 11 counts the bits of the signal transmitted to the frame arranging unit 3 and transmits the value to the control logic circuit 12. The control logic circuit 12 receives the number of bits transmitted. If it corresponds to the head bit allocation value, a time division control signal is generated and applied to the multiplexer 2. The multiplexer 2 converts the selected signal into a 1.544 Mbps signal by the received time division control signal, and counts from this signal to equal the predetermined number of bits, and the time division control signal from the control logic circuit 12. The multiplexer 2 selects a control signal of 64 Kbps and transmits it to the frame arranging unit 3. This process is repeated, and the signal transmitted to the frame arranging unit 3 is repeated as shown in FIG. 3. It is composed.

The frame arrangement unit 3 adds a data stream for stability and reliability of signal transmission to the received signal and arranges it in a frame, and the modulation unit 4 modulates the arranged frame signal into a cap signal. To the signal synthesizing separator 5. The signal synthesizing separator 5 filters the modulated cap signal into a high pass filter, and a voice signal input through the telephone 6 through a low pass filter, and then synthesizes the synthesized cap signal through the telephone line L. Send to device

The signal synthesizing section 5 of the asymmetric subscriber line digital transmission apparatus on the subscriber side receiving the synthesized signal input through the telephone line L separates the synthesized cap signal and the voice signal, and the cap signal is the The demodulator 7 sends the audio signal to the telephone 6, respectively. The demodulator 7 demodulates the cap signal into an original signal and sends the cap signal to the frame reconstruction unit 8, and the frame reconstruction unit 8 decodes an excess data stream (header, CRC, etc.) added to the signal. The demultiplexer 9 'outputs the first received digital signal to the overhead output stage.

Meanwhile, the bit counter 11 counts the number of bits of the digital signal input to the demultiplexer 9 'and transmits the number of bits to the control logic circuit 12, and the control logic circuit 12 references the number of bits. When the number is allocated to the overhead bits, the time division control signal is applied to the demultiplexer 9 'to switch the output signal line to output 1.544 Mbps signal line, and when the number of bits is reached, the next signal line is controlled by the control logic circuit 12. By repeating the process of outputting in turn, the frame signal of FIG. The separated output overhead signal is separated and decoded into overhead signals OVH ₁ , OVH ₂ ,..., OVH ₆ , each having a specific function, through an overhead signal extractor (not shown). (Synchronous acquisition, etc.) will be performed.

When the digital transmission apparatus of the asymmetric subscriber line on the subscriber side transmits information to the apparatus on the information provider side, the signal multiplexing and vice versa except that the high-speed 1.544 Mbps signal for transmitting image information is excluded. The multiplexing process is the same as described above.

However, in the conventional asymmetric subscriber line digital transmission apparatus constructed and operated as described above, 64 Kbps for the menu of image information or the selection thereof. Since the control channel is used for the single purpose of transmission of the control signal that does not have a large amount of data, the availability and efficiency of the line is low, and when a variety of communication services such as Internet service are to be provided, a separate line must be established in addition to the high-speed video line. There was a problem that caused a waste of circuit.

Accordingly, the present invention has been made to solve the above problems, and by using multiplexed control channels to transmit and receive control signals and signals necessary to provide other services together, asymmetric subscriber line digital to efficiently use the control channel It is an object of the present invention to provide a control channel multiplexing device for a transmission device.

1 illustrates a configuration of a conventional asymmetric subscriber line digital transmission device.

(a) is an apparatus on the image information provider side,

(b) is a subscriber side device,

2 is a block diagram illustrating an embodiment of an asymmetric subscriber line digital transmission device in which a control channel multiplexing device according to the present invention is implemented.

(a) is an apparatus on the image information provider side,

(b) is a subscriber side device,

Figure 3 shows the configuration of a frame transmitted in a conventional asymmetric subscriber line digital transmission device,

4 is a block diagram of a frame transmitted from an asymmetric pressure line digital transmission apparatus in which a control channel multiplexing apparatus according to the present invention is implemented.

* Explanation of symbols for main parts of the drawings

L: Telephone line 2, 2 ', 20, 20': Multiplexer

3: Frame array 4: Modulator

5: signal synthesizing part 6: telephone

7: demodulation unit 8: frame reconstruction unit

9, 9 ', 90, 90': Demultiplexer 11: Bit counter

12, 120, 120 ': control logic circuit 20a, 20b: high speed converter

90a, 90b: Low speed converter

The control channel multiplexing apparatus of the asymmetric subscriber line digital transmission apparatus according to the present invention for achieving the above object, the multiplexing means for multiplexing a plurality of input signals, distribution means for distributing the received demodulated signal, and the multiplexing And a control means for time-dividing control of signal selection and distribution of the distribution means and the distribution means, the asymmetric subscriber line digital transmission apparatus comprising: a high-speed conversion of a plurality of low-speed digital signals to the multiplexing means as synchronous digital signals, respectively. Fast converting means for inputting; And low speed converting means for converting a plurality of synchronous digital signals distributed by the distribution means into low speed digital signals, respectively, and outputting the low speed digital signals, wherein the control means comprises a digital signal remotely transmitted from the multiplexing means. Respectively detects the digital signals received by the distribution means, and based on the multiplexing times of the plurality of high-speed conversion input synchronous digital signals and separate transmission signals of the multiplexing means, and the plurality of synchronous digital signals of the distribution means. And controlling the distribution time of separate reception signals, respectively.

In the control channel multiplexing apparatus of the asymmetric subscriber line digital transmission apparatus according to the present invention configured as described above, first, the high speed converting means converts a plurality of low speed digital signals into synchronous digital signals and transmits them to the multiplexing means. .

The control means controls the output selection time of the plurality of high-speed converted digital signals and the separate transmission signal input to the multiplexing means based on the amount of digital signals selectively output from the multiplexing means. A plurality of input signals are time-divisionally selected and output, and the output signals are framed according to a transmission standard, converted, synthesized, and transmitted to a receiver.

Further, the distribution means receives a high speed synchronous digital signal extracted from the frame after being transmitted from the transmitting side and separated and demodulated, and distributes the same to the output terminal. The control means is adapted to the amount of the synchronous digital signal input to the distribution means. The distribution selection time of each of a plurality of synchronous digital signals and a separate received signal is controlled based on the above, and accordingly, the distribution means decomposes and inputs the high speed synchronous digital signal to the corresponding output terminal. The digital signals of are converted at low speed by the low speed conversion means and output as low speed digital signals, respectively.

Hereinafter, an operation of an embodiment of a control channel multiplexing apparatus of an asymmetric subscriber line digital transmission apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 (a) shows a configuration of an embodiment in which a control channel multiplexing device of an asymmetric subscriber line digital transmission device according to the present invention is implemented in an information provider side device, wherein a low-speed asynchronous digital signal of 38.4 Kbps signal and Fast converters 20a and 20b which receive 9.6 Kbps signals and convert them into synchronous signals of 48 Kbps and 16 Kbps, respectively; A multiplexer 20 that receives the converted 48Kbps signal, 16Kbps signal, overhead signal, and 1.544Mbps signal and selectively outputs the received 48Kbps signal according to a time division control signal; A frame arrangement unit 3 performing the same function as in the conventional asymmetric subscriber line digital transmission apparatus; A signal synthesis separator 5; Demodulation section 7; Frame reconstruction unit 8; Bit counter 11; A demultiplexer (90) for separating and outputting an overhead signal, a 48Kbps signal, and a 16Kbps signal from a high-speed data sequence extracted by the frame reconstruction unit (8) by a time division control signal; Low-speed converters 90a and 90b for converting the separated synchronous 48Kbps signal and 16Kbps signal into asynchronous 38.4Kbps signal and 9.6Kbps signal; And the time division control signal for separating the image signal channel (1.544 Mbps) and the control channel (64 Kbps) as well as the multiple signal separation of the control channel from the number of transmission bits of the input / output digital signal transmitted from the bit counter 11. And a control logic circuit 120 for outputting.

In addition, in the subscriber side apparatus of the asymmetric subscriber line digital transmission apparatus in which the control channel multiplexing apparatus of FIG. 2 (b) is implemented, the multiplexer 20 'is controlled by the multiplexer 20' under the control logic circuit 120 '. The 16Kbps signal is multiplexed and the demultiplexer 90 'is identical to the configuration of Figure 2 (a) except that it is demultiplexed into an overhead signal, 1.544Mbps signal, 48Kbps and 16Kbps signal.

In the information provider side of the asymmetric subscriber line digital transmission apparatus in which the control channel multiplexing apparatus according to the present invention is constructed as described above, the asynchronous signals of 38.4 Kbps and 9.6 Kbps to which the high-speed converters 20a and 20b are input are first input. The signal is converted into a synchronous signal of 48 Kbps and 16 Kbps, each of which is increased to correspond to a control channel of 64 Kbps, and transmitted to the multiplexer 20. The multiplexer 20 transmits an overhead signal including a signal synchronization bit to the frame arranging unit 3 during initial transmission. The digital signal transmitted in this manner is transmitted by the bit counter 11. The number of bits is detected and transferred to the control logic circuit 120.

If the number of bits received is equal to the number of bits allocated to the overhead signal, the control logic circuit 120 generates a time division control signal and applies it to the multiplexer 20 to apply the currently selected output signal to the overhead signal. Switch to an image signal of 1.544Mbps. The control logic circuit 120 applies a time division control signal to the multiplexer 20 again when the number of output bits reaches 1544 while the high speed image signal is outputted so that a signal input of synchronously converted 48Kbps is selected and output. When the number of output bits of the corresponding signal reaches 48, the 16Kbps signal is selected and output again. Then, when the number of output bits of the 16 Kbps signal is 16, the next overhead signal is selected and output again, and this operation is repeatedly performed.

4, the transmission signal configured as shown in FIG. 4 is properly signal-processed through the frame arranging unit 3, the modulator 4, and the signal synthesizing separator 5, and transmitted to the apparatus on the subscriber side as in the prior art. The signal is again input to the demultiplexer 90 'through the signal synthesis separator 5, demodulator 7 and frame reconstruction unit 8 of FIG.

On the other hand, in the subscriber-side device, when the control logic circuit 120 'controls the demultiplexer 90' to select the signal time interval of the control channel (64 Kbps), the input bit is transmitted to the 48 Kbps output terminal. After checking the number of bits provided through the bit counter 11, when the number of bits identified is 48, the input bits are distributed to the next 16 Kbps output terminal, so that the 64Kbps signal and the 48Kbps and 16Kbps signals are separated and output. The 48Kbps and 16Kbps signals separated and output as described above are converted into asynchronous signals of 38.4Kbps and 9.6Kbps by the low-speed converters 90a and 90b, respectively.

In the case where a signal is transmitted from the subscriber's transmission device (Fig. 2 (b)) to the information provider's transmission device (Fig. 2 (a)), the signal interval of 1.544 Mbps is omitted in Fig. 4, and thus multiplexing is performed. And the time period of the demultiplexing is excluded from the time division control signal, so that only the signals of the multiplexed control channel are transmitted, and then separated into the corresponding low speed signal.

Accordingly, the subscriber can be provided with a communication service such as the Internet in addition to a high speed video service such as movie watching without installing a separate line, and multiplexes the 16Kbps signal line back to a signal of 9.6Kbps and 2400 bps, and a low speed 2400 When the bps signal can be used for low speed remote control (telemetering, home automation) or the like, the utility of the line can be further increased.

The control channel multiplexing device of the asymmetric subscriber line digital transmitter according to the present invention, which is constructed and operated as described above, provides a communication service such as providing the Internet without providing a separate line by multiplexing a high speed control channel communication capacity. Efficient use is a very useful design that has the effect of eliminating the cost of line waste and line installation.

Claims (4)

An asymmetrical subscriber line including multiplexing means for multiplexing a plurality of input signals, distribution means for distributing a received demodulated signal, and control means for time-division control of signal selection and distribution of the multiplexing means and the distribution means. A digital transmission apparatus comprising: high speed conversion means for converting a plurality of low speed digital signals at high speed and inputting the plurality of low speed digital signals as synchronous digital signals to the multiplexing means, respectively; And low speed converting means for converting a plurality of synchronous digital signals distributed by the distribution means into low speed digital signals, respectively, and outputting the low speed digital signals, wherein the control means comprises a digital signal remotely transmitted from the multiplexing means. Respectively detects the digital signals received by the distribution means, and based on the multiplexing times of the plurality of high-speed conversion input synchronous digital signals and separate transmission signals of the multiplexing means, and the plurality of synchronous digital signals of the distribution means. And controlling distribution times of separate reception signals, respectively. The apparatus of claim 1, wherein the separate transmission signal is an overhead signal and a high speed digital signal of 1.544Mbps, and the separate reception signal is an overhead signal. The apparatus of claim 1, wherein the separate transmission signal is an overhead signal, and the separate reception signal is an overhead signal and a high speed digital signal of 1.544 Mbps. 4. The apparatus of claim 1, 2 or 3, wherein the plurality of low speed digital signals are asynchronous signals of 38.4 Kbps and 9.6 Kbps, respectively.