KR20000016209A - Method for data transmission between master station and slave station - Google Patents

Abstract

PURPOSE: The method is to improve to exclude the usage of a repeater as a whole or partially. CONSTITUTION: The method is to transmit data between a master station(1) and a slave station(2), and the transmitted data is included in data frames supplied continuously to the master station and includes some amount of data. The method is characterized by that data of above data frames supplied to the master station are mixed with data of data frames supplied before or after in each case and are distributed across a plurality of new-generated data frames transmitted simultaneously through a plurality of transmission links(31, 61) by a plurality of transmission apparatuses.

Description

How to transfer data between master and slave stations

The method is known, for example, in the field of ISDN, for example, the main station can be a component of a so-called NT (network termination) unit and the end station can be a component of a so-called LT (line termination) unit and / or vice versa. have. A transport link for transmitting data, also called a U-interface, is connected between an NT unit located at each ISDN subscriber and an LT unit located at an ISDN operator's telephone exchange.

The data to be transmitted by the master station each contains a predetermined amount of data and is included in the data frames supplied to the master station.

The master station extracts the data to be relayed from it to the end station and sends the data (perhaps with newly added control data) to the end station via the U-interface.

In this case, a problem arises in that the transmission range is limited; The transmission range is approximately 5.5 km under the techniques and methods currently used in the ISDN system, that is, the main station, the final station, the data transmission method, the data transmission speed, and the type of transmission link (cable type) currently used.

If the master station and the slave station are more than 5.5km apart, the data needs to be reproduced and amplified more than once in between. This may be done for example by so-called repeater units provided along the transmission link.

However, in general, it is expensive to provide such repeaters, in particular to install (inquire) and power them.

It is therefore an object of the present invention to improve the method according to the preamble of claim 1 such that the use of repeaters is wholly or partially excluded.

Summary of the Invention

This object is achieved according to the invention by the features of claim 1.

This means that the data of the data frames supplied to the master station is supplied before or after each of the data frames supplied to the master station over a plurality of newly generated data frames transmitted essentially simultaneously by the plurality of transmission devices over the plurality of transmission links. It is mixed with the data and distributed.

The generation of a plurality of new data frames from raw data frames that are continuously supplied to the master station and the simultaneous transmission of the new data frames by a plurality of parallel-connected master stations over a plurality of parallel transport links are the data on the respective transport link. Reduce the transmission speed The contraction of the transmission spectrum associated therewith may in turn be placed in a frequency band that relatively weakly attenuates the transmitted data or a signal corresponding to the data when the spectrum is used for data transmission. Reducing attenuation of data transmitted on the transmission link has the positive effect of increasing the transmission range on the other hand.

If the data flows that are continuously input to the master station are, for example, separated into two data flows, and they are sent by the two transmitting devices to the end stations in parallel over two transport links, each at ½ of the data rate, the range is It can be increased from 5.5 km to about 7 km using techniques and methods currently used in ISDN systems.

Thus, a method has been found that can completely or partially eliminate the use of repeaters.

In addition, generating new data frames by voweling separately from data of a plurality of raw data frames is combined in each data frame with the data to be treated identically or similarly, so that the latter is assigned to the end or end station. It can be handled in a distinctly simpler and more error-resistant form.

Advantageous improvements of the invention are the subject matter of the dependent claims.

The present invention relates to a method according to the preamble of the claims. In other words, a data transmission method between a master station and a slave station assigned thereto, the data transmission method relates to a data transmission method when the data to be transmitted is continuously supplied to the master station and included in data frames each including a predetermined amount of data. .

1 shows a first embodiment of an apparatus suitable for carrying out the method according to the invention.

2 is a schematic diagram of the content (format) of a data frame input to a master station according to FIG. 1;

3 is a schematic diagram illustrating the generation of new data frames from a data frame input according to FIG. 2 input to a master station according to FIG.

4 shows a second embodiment of an apparatus suitable for carrying out the method according to the invention.

The invention is explained in more detail with reference to the examples and drawings.

The transmission system shown schematically in block diagram in FIG. 1 may be considered a component of an ISDN system, which comprises a master station 1, a slave station 2, and a transmission link 3.

The master station 1 is a component of the NT unit of the ISDN system, and includes a first transmitter 11, a second transmitter 12, a data frame conversion unit 13, and a control unit 14.

The slave station 2 is a component of the LT unit of the ISDN system, and includes a first receiver 21, a second receiver 22, a data frame conversion unit 23, and a control unit 24.

The transport link 3 comprises two line pairs 31 and 32 and is a practical implementation of the U-interface connecting the NT unit and LT unit of the ISDN system. Exactly on this transport link the range can be increased using the method according to the invention.

The resulting transmitters 11, 12 are also composed of transmit / receive units (receivers) in which both the transmitters 11, 12 and the receivers 21, 22 have suitable external circuit elements. The receivers 21 and 22 may be used as transmitters to allow bidirectional communication.

The transmitters 11, 1 and receivers 21, 22 are implemented in this embodiment by means of a Siemens module PEB 2091 IEC-Q v4.x, each with an appropriate reference circuit element.

The data frame conversion units 13 and 23 are implemented in this embodiment by two Siemens modules PEB 2054 EPIC-S, respectively.

The control units 14, 24 are implemented by microprocessors, microcontrollers and the like.

The operation of the transmission system of FIG. 1 will be described.

Data transmitted through the transmission link 3 is included in data frames continuously supplied to the data frame conversion unit 13 through the input terminal E. These data frames are called IOM-2 data frames because they are supplied to a data frame conversion unit via a so-called IOM-2 interface.

The definition of the IOM-2 interface and the IOM-2 data frames that can be transmitted through it is by the applicant and is well known in the art. For simplicity, hereinafter, the IOM-2 interface is referred to as an IOM interface, and the IOM-2 data frame is referred to as an IOM data frame.

In this embodiment, the IOM data frames are each 32 bits long, and these bits are made from (user) data or control data for the transmission devices 11 and 12 to be transmitted over the transmission link 3. The content or format of such an IOM data frame is shown in FIG. According to this, the IOM data frame has 8 bits of B1-data, 8 bits of B2-data, 8 bits of monitor data, 2 bits of D-data, 4 bits of C / I data, 1 bit of MR-data, and 1 Contains the bit's MX-data.

The user data to be transmitted by the transmitting devices 11, 12 (possibly with additional control data for the receiving devices 21, 22) are B1-data, B2-data, and D-data; The monitor data, C / I data, MR-data and MX-data are control data for controlling the transmission devices 11 and 12.

The data frame conversion unit 13 has control terminals and can be controlled by the control unit 14 through this. In this embodiment, the control unit 14 controls the data frame conversion unit 13 so that two IOM data frames that are successively inputted in each case are separated into two data frames (hereinafter referred to as "IOM ^* data frame"). In control, the IOM ^* data frames can be transmitted to the transmitting device 11, 12 in parallel via separate interfaces, and further processed therein, ie as IOM data frames. In addition, the control unit 14 controls the data frame conversion unit 13, in which the latter is continuously input to the data frame conversion unit 13 at 4 ms, i.e., 4000 data frames per second, via a separate (IOM ^* ) interface. Control to output the IOM ^* data frames with a time extension at the respective frame rate, which is only ½ of the frame rate of the IOM data frames.

3 shows the conversion of consecutive IOM data frames into parallel IOM ^* data frames performed in the data frame conversion unit 13. In the example shown, two consecutive IOM data frames (middle row of FIG. 3) are separated into a first IOM ^* data frame (lower row of FIG. 3) and a second IOM ^* data frame (upper row of FIG. 3). . Which user data and control data portion of the IOM data frame is moved to where in the IOM ^* data frame is clearly shown by the arrows in FIG. 3 and no further explanation will be required.

In essence, dividing IOM data frames into IOM ^* data frames, preferably into IOM ^* data frames having the same or at least similar structure in the same length, can be performed without strict limitations in most cases. However, the separation shown in FIG. 3 is particularly noteworthy in two respects. First, the control data of the IOM data frames (control data for controlling the respective transmission devices 11 and 12) is treated as an indivisible and indivisible whole, and then B1 data of two consecutive IOM data frames. The portion and the B2 data portion are concentrated in each IOM ^* data frame, so that the first IOM ^* data frame does not have a B2 data portion, and the second IOM ^* data frame does not have a B1 data portion.

The result of the first feature described above is that the control of the respective transmission devices 11, 12 can be performed without being disturbed by changes in the control data in successive IOM data frames.

The result of the second feature described above is that only the B1 data portion or only the B2 data portion need to be considered, without having to consider both the B1 data portion and the B2 data portion respectively in the next processing or evaluation of such data frames. In some cases, this greatly simplifies the subsequent processing or evaluation of such data frames or further enhances error-tolerant.

The conversion of two consecutive IOM data frames into two parallel IOM ^* data frames outputs from the data frame conversion unit 13 at the rate of ½ of the data transmission rate while the IOM ^* data frames are each ½ of the data transmission rate. And then to be processed. While 125 ms is required to transmit IOM data frames, IOM ^* data frames require twice as long to transmit, 250 ms due to parallel transmission and processing. Thus, IOM ^* data frames may be time extended relative to IOM data frames (see FIG. 3 in this regard).

The IOM ^* data frames output in parallel from the data frame conversion device 13 are supplied to the first transmission device 11 and the second transmission device 12 through separate transmission lines. There, the IOM ^* data frames are reformatted, and new control data (control data for the receiving devices 21, 22) are supplied so that the U ^* data frames (transmission link 3 is a so-called U interface). Is output as. U ^* data frames are placed on each transmission line 31, 32 at a data transfer rate of only one half of the data transfer rate when the same amount of data is transmitted on only one data transfer line in the form of a non-separated U data frame.

Dividing a pure continuous data stream (at input line E of data frame conversion device 13) into two parallel data streams (between transmission line 31 and transmission line 32) reduces the overall data transfer rate. Without this, the data transmission speed on each transmission line can be halved. The contraction of the transmission spectrum associated with it on each transmission line allows for a relatively small reduction in the data or data frames transmitted or to be transmitted and consequently an increase in the transmission range. The distance between the master station 1 and the slave station 3 connected to it beyond the transmission line can be increased as a result without the insertion of a repeater. This means that in the case of techniques and methods currently used in ISDN systems, a range increase of approximately 5.5 km to 7 km can be obtained. The result is a savings in the number of repeaters which cannot be ignored, especially in the case of large distances.

The U ^* data frames outputted by the transmission devices 11, 12 onto the transmission lines 31, 32 are received by the reception devices 21, 22 of the terminal station 2, and are modified into IOM ^* data frames to modify the data. Supplied to the frame converting device 23 (again in parallel) and combined there under the control of the control unit 24 to form an IOM data frame, which is likewise continuously output through the output terminal A for subsequent processing. .

A second embodiment of the present invention is described with reference to FIG. The method according to the invention will be applied here in the case of the master station of the repeater.

The transmission system schematically shown in block diagram in FIG. 4, once again, may be a component of an ISDN system and comprises a first repeater 4, a second repeater 5 and a transmission line 6.

In this embodiment, the (normal) NT unit (not shown) via the input terminal E (U interface) or the (normal) next repeater (not shown) of the ISDN transmission system partially shown in FIG. 4. The first repeater 4 which can be connected to includes a slave station, a master station and a control unit 44.

In this embodiment, the (typical) LT unit (not shown) via the output terminal A (U interface) or the next relay (typical) (not shown) of the ISDN transmission system partially shown in FIG. The second repeater 5, which may be connected to the terminal, likewise comprises a slave station, a master station and a control unit 54, and furthermore, the second repeater 5 provides a suitable clock signal for the master station and the slave station and the components contained therein. It has a clock control unit for generating.

The transmission link 6 comprises two line pairs 61 and 62 and is a practical implementation of the U interface connecting the repeaters. It is this range of ISDN U interfaces that is increased by using the method according to the invention in this embodiment.

The end station of the first repeater 4 is formed by the receiving device 41. The master station of the first repeater 4 includes a first transmitter 42 and a second transmitter 43.

The end station of the second repeater 5 is formed by the first receiving device 51 and the second receiving device 52. The master station of the second repeater 5 comprises a transmitter 53.

The receiving device 41 and the transmitting device 42 and 43 of the first repeater 4 and the receiving device 51 and 52 and the transmitting device 53 of the second repeater 5 are transmitting and receiving units with suitable external circuit elements. (Transmitter and receiver), and as a result, the transmitting apparatuses may also be used as receiving apparatuses, respectively, and the receiving apparatuses may also be used as transmitting apparatuses, thereby enabling bidirectional communication.

The transmitter and receiver in this embodiment are implemented by Siemens module PEB 2091 IEC-Q v5.1, each with suitable external circuit elements.

In the case of the first embodiment, the control units 44, 54 are implemented by microprocessors, microcontrollers and the like.

The clock control unit of the second repeater 5 consists of a PLL circuit 54, which provides an appropriate clock signal with respect to the evaluation of the control signal received at the receiver at each transceiver of the second repeater.

The function of the transmission system shown in FIG. 4 will be described.

In the case of the embodiment according to FIG. 1, the data to be transmitted via the transmission link 6 is contained in data frames, which are supplied via the input terminal E to the receiver 41 of the first repeater 4. . By the way, unlike in the embodiment according to FIG. 1, these data frames are not IOM data frames-since they are fed to the first repeater (from the NT unit or the next repeater) via the U interface-different data frames hereafter referred to as U data. It is called a frame.

The U data frames comprise a predetermined number of bits occupied by user data (B1 data, B2 data, and D data) and control data for controlling the receiver 41. However, any further details of secondary interest at present can be referred to the corresponding specifications of the ETSI and ANSI standards.

Thus, the U data frames are input to the receiver 41 of the first repeater 4 via an input terminal E. FIG. The receiving device 41 has an interface for connecting with the control unit 44. Through this interface, it is possible to exchange data frames as well as control commands between the receiving device 41 and the control unit 44. The use of the same transceiver produces the same result for the transmitters 42, 43. This is in this embodiment, after being converted into IOM data frames in the first embodiment, U data frames received by the receiving device 41 are, for example, by way of it via the IOM interface (as before). Rather than being output to the feeders 42, 43 supplied, it is output to the control unit 44 via a special interface, where it is converted into IOM ^* data frames according to the invention, and only then there are more transmitters Specifically relayed to the interfaces provided for connection with the control unit.

The conversion of the IOM data frames in the control unit 44 is performed similarly to the conversion performed in the data frame conversion device 13 in FIG. 1. In other words, the IOM data frames that are continuously output by the receiver 41 and received by the control unit 44 are distributed among the IOM ^* data frames that can be relayed there and processed in parallel, finally ( After being converted into U ^* data frames, it is transmitted in parallel via a plurality of transmission lines 61, 62 (U interface) by a plurality of transmission devices 42, 43.

In the case of the first embodiment, separating the pure continuous data flow (at the input terminal E of the receiving device) into two parallel data flows (between the transmission lines 61, 62) is parallel transmission lines 61. , 62) has the positive effect that the data transfer rate on FIG. 62 can be halved without reducing the overall data transfer rate. The limitation of the transmission spectrum associated with this makes it possible to place the spectrum in a frequency band in which the data or data frames to which it is transmitted or transmitted suffers a relatively low attenuation, resulting in an increased transmission range. The distance between the first repeater 4 and the second repeater 5 connected thereto or the LT unit connected thereto can eventually be increased (as is the case in the first embodiment). In this way an insignificant number of repeaters can be saved, especially for very large distances.

The second repeater 5, shown in FIG. 4, uses a parallel data stream or a U ^* data frame stream transmitted from the second repeater via transmission lines 61 and 62 in this embodiment to a continuous data stream or a U data frame. Have a mission to recover to the stream.

For this purpose, the U ^* data frames transmitted via the transmission lines 61, 62 are received by the receivers 51, 52 of the second repeater 5, where (in parallel) the IOM ^* data Are converted into frames and output to the control unit 54, where they are converted into (continuous) IOM data frames and relayed to the transmitter 53, and relayed (converted into consecutive U data frames) for subsequent processing. After that, it is output as it is from the output terminal A by the said transmission apparatus.

The modified data frame transmission condition according to the present invention requires a somewhat comprehensive clock signal matching for each transmitting and receiving apparatus, which is the case for both the first embodiment and the second embodiment. To this end, these devices are connected to the control lines and the clock signal lines (as partly shown in FIGS. 1 and 4), which will not be considered further in detail here.

The method according to the invention is not limited to converting two successive IOM data frames in each case into two parallel IOM ^* data frames that can be relayed and continue to be processed. In addition, it is also possible to convert an arbitrary plurality of arbitrary data frames into any number of data frames that can be transmitted and relayed in parallel, in accordance with each requirement, that is to say in particular according to the degree of requirement of the transmission spectrum limitation.

The present invention can also be used outside the ISDN system.

Claims (6)

A method of transferring data between a master station (1; 4) and a slave station (2; 5) assigned thereto, wherein the data to be transmitted is contained in data frames that are continuously supplied to the master station and each has a predetermined amount of data. In the data transmission method between the master station and the slave station, The data of the data frames supplied to the master station is mixed with the data of data frames supplied before or after in each case, so that a plurality of transmission links 31, 32; 61, 62 are provided by a plurality of transmission devices. A method for transmitting data between a master station and a slave station, characterized in that it is distributed over a plurality of newly generated data frames transmitted essentially simultaneously. The method of claim 1, The control data (monitor, C / I, MR, MX) for continuously controlling the interleaved devices contained in the distributed data frame is inseparably whole during the distribution of the data between the newly generated data frames. A data transfer method between a master station and a slave station, characterized in that it is treated as. The method according to claim 1 or 2, User data (B1, B2, D) included in one data frame to be distributed are combined in a modified form while distributing the data between the newly generated data frames. Way. The method according to any of the preceding claims, And the newly generated data frames are transmitted in a time-expanded manner on each data transmission link (31, 32; 61, 62). The method according to any of the preceding claims, A transmission spectrum limited to each transmission link (31, 32; 61, 62) at a reduced data rate is located in the frequency band with the least attenuation of the transmitted data. The method according to any of the preceding claims, The data frames distributed between newly generated data frames are IOM data frames of NT unit, LT unit or repeater unit of ISDN system.