KR0147262B1 - Multiplexing of data - Google Patents

Abstract

The present invention relates to a data multiplexing device. In particular, when multiplexing low-speed data to a subchannel, the present invention relates to a data multiplexing device for maximizing transmission efficiency by generating and multiplexing a subchannel according to a subchannel synchronization pulse. The objective is to generate the same subchannel synchronization pulses in multiple data units, generate and multiplex subchannels based on a common unit unit matching the signal with an external line, and a subchannel synchronization pulse generated in the common unit unit, It is achieved by having a data unit for transmitting the multiplexed transmission data to the outside through the common unit.

Description

Data multiplexing device

1 is a block diagram of a conventional data multiplexing device.

2 is a block diagram of a data multiplexing device applied to the present invention.

* Explanation of symbols for main parts of the drawings

10: Data unit 20: Common unit

20d: subchannel synchronous pulse generator

The present invention relates to a data multiplexing device, and more particularly, to a data multiplexing device for maximizing transmission efficiency by generating and multiplexing a subchannel according to a subchannel sync pulse when low speed data is multiplexed on a subchannel.

The conventional data multiplexing apparatus includes a data unit 10 for multiplexing low-speed data of a subscriber using subchannels, and a data interface with the data unit 10 as shown in FIG. It consists of a common unit unit 20 for multiplexing and matching the preference signal.

Here, the data unit 10 includes subscriber matching units 10a to 10e, a subchannel sync bit generator 10f for generating subchannel sync bits for determining the order of subchannels, and a subchannel for generating subchannels. Subscriber suspensions 10a to 10e obtained in the subchannel generated by the subchannel generator 10g according to the subchannel sync bit generated by the generator 10g and the subchannel sync bit generator 10f. The subchannel multiplexer 10h multiplexes and transmits data.

In addition, the common unit unit 20 includes a channel synchronization pulse generator 20a for generating a channel synchronization pulse, a channel multiplexer 20b, and a line signal matching unit 20c for matching a line signal.

The operation of the conventional data multiplexing device configured as described above will be described in detail. First, six units (5 subscribers per sheet, total number of subscribers = 5 * 6 = 30) of the data unit 10 are used in the common unit unit 20 as a unit. In this case, one subscriber is allocated one frequency band (64 Kbps) in order to multiplex the common unit 20.

For example, the data unit 10 may have five subscribers, and the five subscribers apply transmission data to the subchannel multiplexer 10h through the subscriber matching units 10a to 10e.

At this time, the subchannel generator 10g generates a subchannel and applies the subchannel multiplexer 10h to the subchannel multiplexer 10h. The subchannel sync bit generator 10f performs the subchannel sync bit to determine the order of the generated subchannels. Is generated and applied to the subchannel multiplexer 10h.

Accordingly, the order of the subchannels is determined according to the subchannel synchronization bits inputted to the subchannel multiplexer 10h, and the data output from the subscriber matching units 10a to 10e are multiplexed according to the determined order to form a common unit ( 20).

The transmitted data is received by the common unit unit 20, multiplexed by the channel multiplexer 20b according to the channel synchronization pulses generated by the channel synchronization pulse generator 20a, and transmitted through the preferred signal matching unit 20c. .

However, such a conventional data multiplexing device has low transmission efficiency because only a few bands are available for low-speed subscribers (2.4, 4.8, 9.6Kbps) because the speed of subscribers that match each subscriber matching unit varies from 2.4 to 64 Kbps. There was a losing problem.

That is, in order to determine the order of the subchannels, subchannel sync bits are generated and inserted into the subscriber data and multiplexed. In this case, the subchannel sync bits are generated by each data unit unit, and the 5 subscribers accommodated in one data unit Set the channel order.

Therefore, only 5 subchannels are used when using 2.4Kbps, only 10 subchannels are used when using 4.8Kbps, and the rest cannot be used, resulting in low transmission efficiency.

Accordingly, an object of the present invention is to provide a data multiplexing apparatus in which multiplexing low speed data to a subchannel generates a subchannel according to a subchannel synchronization pulse to maximize transmission efficiency.

Means for achieving the object of the present invention is achieved by having a common unit unit for generating a sub-channel synchronization pulse, and a data unit for generating a sub-channel from the sub-channel synchronization pulse obtained from the common unit unit to multiplex the low-speed data Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram of a data multiplexing apparatus applied to the present invention, which is composed of a data unit 10 and a common unit 20 as in the related art, and is characterized in that a subchannel for generating a subchannel sync pulse in the common unit 20. The synchronous pulse generator 20d was added.

The operation and effects of the data multiplexing device applied to the present invention configured as described above will be described in detail as follows.

First, five subscribers are accommodated in the data unit 10, and the five subscribers apply transmission data to the subchannel multiplexer 10h through the subscriber matching units 10a to 10e.

Accordingly, the subchannel multiplexer 10h multiplexes the transmission data to the subchannels according to the generated subchannel order and transmits the data to the common subunit 20. The subchannel order is as follows.

When the five subscribers are low-speed subscribers, the subchannel sync pulse generator 20d in the common subunit 20 generates subchannel sync pulses and supplies them to each data unit 10 (10'10).

The data units 10, 10 ', and 10 that have received the subchannel synchronization pulses are supplied with subchannel synchronization pulses having the same phase and timing, and the subchannel sequence is set to 1 by starting the subchannel synchronization pulses. It is decided to -20.

In this way, the order of the subchannels is the same for the mode data units multiplexed on the same common unit 20 (in the present invention, only three data units are discussed in the embodiment 10, 10 ', and 10).

That is, in the related art, since each data unit arbitrarily determines the order of subchannels without a reference pulse for determining the order of subchannels, the order of subchannels between each data unit is different, so that the same channel (64 Kbps) The subchannels could not be divided and used by multiple data units.

However, in the present invention, in order to increase the transmission efficiency, when data of a low speed subscriber is transmitted, the subchannel order of one channel (64 Kbps) allocated is the same, so that each data unit can be used separately.

For example, by dividing into 20 subchannels, one subchannel is used for 2.4 Kbps, two subchannels for 4.8 Kbps, and four subchannels for 9.6 Kbps. In this case, one channel (64 Kbps) is used. ), Data transmission of 20, 10, and 5 slow subscribers is possible.

The transmission data multiplexed into the subchannels by the above operation is applied to the channel multiplexer 20b in the common subunit 20, and the operation of the preferred signal matching unit 20c is the same as the conventional technology.

As described in detail above, the present invention generates sub-channel synchronization pulses and supplies them to each data unit in common, so that the order of sub-channels is the same. Therefore, the low-speed data of subscriber matching in the data unit is allocated to an arbitrary channel. Since the channel can be freely multiplexed, the transmission efficiency can be maximized.

Claims (3)

The same subchannel sync pulses are generated in multiple data units, the common unit unit matching a signal with an external line, and the subchannels are generated and multiplexed based on the subchannel sync pulses generated from the common unit unit, and multiplexed. And a data unit for transmitting the transmitted data to the outside through the common unit. 2. The common unit unit of claim 1, wherein the common unit comprises: a channel synchronous pulse generator for generating a channel synchronous pulse, a subchannel synchronous pulse generator for generating a subchannel synchronous pulse and supplying the data unit to the data unit; And a channel multiplexer for multiplexing the data transmitted from the data unit according to the channel synchronization pulses generated by the signal generator, and a line signal matcher for matching the channel multiplexer with an external preference signal. 2. The data unit of claim 1, wherein the data unit includes a subchannel generator for generating a subchannel based on a subchannel sync pulse generated by the common unit and a part for generating sync bits based on the subchannel sync pulse. And a sub-channel multiplexing unit for multiplexing the low-speed data obtained from the channel matching bit generating unit and the sub-channel generating unit according to the sub-channel synchronizing bits to the common channel unit. One data multiplexing device.