KR100420836B1 - Transmission network enhancement apparatus of communication - Google Patents

Abstract

PURPOSE: A transmission network extending apparatus of a communication system is provided to make a local station compact by using a module having a transmission network interfacing function and allow terminals to transmit data to each other by connecting every type of transmission network to a base station. CONSTITUTION: An RF processor(120) amplifies and down-converts a signal received by an antenna(110) to generate an RF signal, and up-converts and amplifies the RF signal to radiate it through the antenna(110). The first signal transmitting/receiving unit(130) converts the RF signal into compressed digital data and transmits it to a host station(200), receives the digital data, restores it to the RF signal and transmits it to the RF processor(120). The second signal transmitting/receiving unit(210) receives the compressed digital data, restores it to the RF signal, converts the RF signal into compressed digital data, and transmits it to a local station(100). A digital processor(220) processes the restored RF signal to packet type data, transmits it to an exchange(230), converts the packet type data into an RF signal, and transmits it to the second signal transmitting/receiving unit(210).

Description

Transmission network enhancement apparatus of communication system

The present invention relates to a transmission network extension device of a communication system.

More specifically, by using a signal compression / restoration unit having a large capacity and a real-time compression rate and transmission rate and a module having a network matching function, it is possible to miniaturize its own station and to connect all kinds of transmission networks to a base station, thereby enabling data transmission between terminals. The present invention relates to a transmission network extension device of a communication system.

1 is a block diagram schematically illustrating a conventional communication system, as illustrated, an RF processor 20 for amplifying an RF signal transmitted and received through an antenna 10 and converting a frequency of an RF signal; The RF processor 20 converts the frequency-converted RF signal into packet-type data and transmits the packet-type data to the switching device 50, and transmits the packet-type data transmitted from the switching device 50 using a digital processing method. It is composed of a digital processor 30 for processing the signal and output to the RF processor 20.

Reference numeral 40 denotes a transmission line connection unit that matches the digital processing unit 30 and the transmission network so that data in packet form can be smoothly transmitted and received between the digital processing unit 30 and the switching device 50.

The RF signal generated by the above-described digital processor 30 refers to a signal such as a base band signal, for example.

In the general digital mobile communication system having the above-described configuration, the switching device 50 and the base station BTS are connected by wire lines such as E1 and T1 through the transmission line connection part 40.

At this time, the switching device 50 transmits the data in the form of a packet compressed voice signal to the digital processing unit 30 of the base station. The digital processing unit 30 of the base station generates an RF signal to radiate the packet data through the antenna 10 using a unique digital processing scheme.

In this case, the above-described digital processing method may include various methods such as IMT2000, CDMA, TDMA, and AMPS.

Meanwhile, the RF signal generated by the digital processor 30 is transmitted to the RF processor 20. The RF processor 20 then amplifies and converts these RF signals into a frequency that is easy to transmit on the air, and radiates onto the air through the antenna 10.

On the other hand, a brief description of the reverse process of the above-described process, first, the signal generated on the terminal is transmitted to the RF processing unit 20 of the base station through the antenna 10, the RF processing unit 20 amplified and down-converted the frequency Lowers.

As described above, the RF processor 20 converts the signal received through the antenna to have a low frequency and then outputs the signal to the digital processor 30, and the digital processor 30 converts the RF signal into compressed packet data. After transmitting to the exchanger 50 through the E1, T1 wired network.

In this case, the transmission line connection unit 40 matches the digital processing unit 30 with the wired network so that the packet data output from the digital processing unit 30 can be smoothly transmitted to the switching device 50.

The wired network described above is shown in the figure as a transmission network.

However, the base station in the prior art as described above has a digital processing part and an RF processing part and is a collection of control parts for driving them, and in the case of an outdoor type in order to enable its own magnetic operation, a heat sink ( Additional devices such as heat sinks, power supplies, environmental monitoring devices, controls, security devices, etc. are needed.

Of course, even indoor type, indoor type equipment, fire fighting equipment, storage batteries, etc. are required.

Therefore, in order to implement an existing base station, a separate building must be provided in the case of the outdoor type, and in the case of the indoor type, there is a problem that the scale becomes large enough to consume one floor of the building.

Of course, at present, each mobile communication service provider has practically significant effects by extending the service range by introducing a repeater-type device in the shaded area to overcome the technical limitations described above. It is not a complete solution.

The repeater has no signal processing at all, and has only the purpose of amplifying the electric field strength of the RF signal emitted from the base station to increase service coverage. The call capacity depends solely on the capacity of the mortgage station. It is reasonable to classify it as an additional device of the existing base station system.

Accordingly, an object of the present invention is to locate a digital processing part in charge of call processing in the mother station so as to solve the above-mentioned problems, compress the RF signal generated from the digital processing part located in the mother country, convert it into a digital signal, and then It transmits the signal to the module that compresses, decompresses, and RFizes it, and processes this signal in its own RF processing part and emits it on the air, while compressing the RF signal received through the local antenna and converting it into digital signal. The present invention provides a transmission network extension apparatus for a communication system for transmitting to a digital processing part of an exchange through the digital processing part of the switching center, and processing the packet data in the form of a packet in the digital processing part of the switching center.

1 is a block diagram schematically illustrating a conventional communication system;

2 is a block diagram illustrating an embodiment of a transmission network expansion apparatus of a communication system according to the present invention;

3 is an internal block diagram of a signal transmission and reception apparatus applied to FIG. 2, and FIG. 4 is another embodiment of the present invention.

* Description of Signs of Main Parts of Drawings *

100: marks

110: antenna

120: RF processing unit

130: first signal transmission and reception unit

200: home country

210: second signal transmission and reception unit

220: digital processing unit

230: exchange device

a: signal compression / recovery unit

b: matching module

In order to achieve the above object, the present invention provides a communication system in which a plurality of stations are connected to one mother station through a transmission network so that communication between mobile terminals can be performed, and the apparatus of the present invention provides digital data compressed through a transmission network. Receives the data in the form of an RF signal, restores the RF signal, amplifies and upconverts it, radiates it through an antenna, converts the RF signal transmitted from the mobile terminal into compressed digital data form, and transmits it to the mother station through the transmission network. It converts the data in the form of the own station and the packet transmitted from the switching device into the compressed digital data type data and transmits it to the local station through the transmission network. It is configured as a mother station which receives and converts it into packet data and delivers it to the switching device. Characterized in that.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating an embodiment of a transmission network expansion apparatus of the present invention communication system, Figure 3 is an internal block diagram of a signal transmission and reception apparatus applied to FIG.

As shown, in the communication system of the present invention, a plurality of stations 100 are connected to the mother station 200 as in a general communication system, and the configuration of the present invention is different from the general case as follows. do.

First, the local station 100 receives data in the form of digital data compressed through a transmission network, restores an RF signal, amplifies and upconverts the restored RF signal, radiates it through an antenna, and compresses an RF signal transmitted from a terminal. The data is converted into data in the form of digital data and transmitted to the mother station 200 through a transmission network. The detailed configuration is as follows.

An RF signal is generated by amplifying and downconverting a signal received by the antenna 110, and an RF processor 120 for upconverting and amplifying the RF signal to radiate through the antenna and the RF processor 120 output from the above-described RF processor 120. Transmitting the compressed digital data form data generated by converting the RF signal to the mother station 200, receiving the compressed digital data form data transmitted from the mother station 200, restored to the RF signal and transmitted to the RF processor The first signal transmitting and receiving unit 130 is composed of.

Next, the mother station 200 converts the data of the packet form transmitted from the switching device 230 into an RF signal, and converts the converted RF signal into data of the compressed digital data form to the local station 100 through the transmission network. Transmitting the data in the form of compressed digital data transmitted from the local station 100 to an RF signal, converting the data into a packet form, and outputting the data to the switching device 230. The detailed configuration is as follows.

The second signal receiving the above-described compressed digital data form of the local station 100 through the transmission network to restore the RF signal, converts the RF signal into data of the compressed digital data form and transmits the data to the local station 100 Transmitter and receiver 210 and the RF signal restored by the above-described second signal transmitter and receiver 210 are processed as packet data and transmitted to the exchange apparatus 230, and the packet transmitted from the exchange apparatus 230 It is composed of a digital processor 220 for converting the data of the form into an RF signal to transmit to the second signal transmitter, receiver 210. In FIG. 2, although the exchange station 230 is included in the mother station 200, a transmission line connection unit (not shown) connected to the digital processing unit 220 is further provided in the mother station 200, and the transmission line connection unit is provided. It is also possible to be connected to an exchange device located at a remote location through a wired network such as E1, T1.

The first signal transmitter / receiver 130 and the second signal transmitter / receiver 210 may include a signal compression / recovery unit (a) having a real-time large-capacity compression ratio and a transmission rate, and the local station 100 connected through a transmission network. The mother station 200 includes a matching module (b) for matching the local station 100 and the mother station 200 to a transmission network so as to transmit and receive a signal between each other.

In the present invention, the transmission network between the first signal transmitter / receiver 130 and the second signal transmitter / receiver 210 includes not only a conventional wired network but also a wireless network such as WLL, By semantics, it also includes infrastructure networks in the form of LOCAL LOOP.

In addition, the exchange apparatus 50, 230 used conventionally and in this invention means the exchange station which we generally speak, and was called the exchange apparatus for convenience in order to raise the objective of this invention. In addition, the above-mentioned signal compression / recovery unit (a) compresses and transmits the BASE BAND signal (0 to 630 Khz) in the CDMA technology, for example, a digital signal of 1.2288 Mbps and at the same time, and restores the received compressed signal again ( Electrical matching, A / D converting (re-digitize baseband), compression (coding using compression algorithms), transmission over transmission lines, decompression (restore: coding using reverse compression algorithms), D / A Performs the conversion (convert the re-digitized signal into a baseband signal) and RF matching (connect to TRANCEVER (which up-converts the baseband)).

The operation of the transmission network expansion apparatus of the communication system according to the present invention configured as described above will be described in more detail with reference to the accompanying drawings.

First, when packet-type data to be transmitted from the switching device 230 of the mother station 200 to the terminal is transmitted to the digital processing unit 220, the digital processing unit 220 receives the signal and performs digital processing to obtain an analog signal. An RF signal is generated and transmitted to the second signal transmitter and receiver 210.

Then, the second signal transmitter / receiver 210 converts the RF signal into data in the form of compressed digital data and transmits it to the local station 100 through the transmission network.

On the other hand, the station 100 receives the data in the form of compressed digital data transmitted through the above-described process through the first signal transmission and reception unit 130, the first signal transmission and reception unit 130 is received Restore the data in the form of digital data to the RF signal. The RF processor 120 of the slave station 100 receives and amplifies the restored RF signal, upconverts it, and then radiates it onto the air through the antenna 110.

Of course, the signal transmitted from the terminal is transmitted to the mother station 200 through the above-described process, which is briefly described as follows.

The RF processor 120 of the local station 100 amplifies and downconverts an RF signal received through the antenna 110, and then transmits the RF signal to the first signal transmitter and receiver 130.

Then, the first signal transmitter and receiver 130 converts the down-converted RF signal into data in the form of compressed digital data and transmits it to the mother station 200 through the transmission network.

Meanwhile, the second signal transmitter / receiver 210 of the mother station 200 receives the data in the compressed digital data form described above, restores the original RF signal, and transmits the original RF signal to the digital processor 220.

Then, the digital processing unit 220 processes the restored RF signal into data in a packet form and transmits it to the exchange apparatus 230.

On the other hand, in the present invention, the digital processing unit installed remotely is installed in the base station (local station in the present invention) in the prior art, because of the performance limitation of the wired network. This is because of the preconceived notion that only low-compression digital data can be transmitted in the existing wired network.

However, various current compression technologies have been developed to compress RF signals and transmit them through existing wired networks, and the present invention uses these points to form digital processing parts at remote locations and form them as part of an exchange station.

Here, the first and second signal transmitters and receivers 130 and 210 are shown in FIG. 3 and attached to the signal compression / restore unit (a) having a large compression ratio and a transmission rate in real time, as described in the configuration. Since the module (b) has a transmission network matching function, it can be directly applied to a communication system having a wired network currently used. In this case, instead of a wired network, a wireless network, and moreover, an infrastructure network of a local loop type may be applied.

In other words, although not attached to the drawing, if the track is miniaturized and attached to the antenna, or if the track is integrated with the antenna, the track is provided with a connector portion for selectively connecting the wired network as well as the wireless network and the infrastructure network. Any one of the various transmission networks as described above may be selected and used. At this time, since the first and second signal transmission / reception units 130 and 210 applied to the present invention have excellent data resilience, no matter how far the transmission / reception distance is, As a block diagram implemented to allow long-distance transmission without loss, the system to implement the present invention is to operate the digital processing unit 220 in charge of the unique processing of the communication method to operate as a part of the mother station, and to convert the RF signal Remotely transfers data in the form of digital data (baseband signals) just before Although the present invention has been described as being limited to a system for transmitting data, the present invention can be implemented as a system capable of transmitting a signal regardless of a transmission / reception distance using a specific transmission line. That is, the mother station 200 to which the present invention is applied. The signal transmits a signal to a station located at various distances through the above-described transmission network. In this case, when the station 100 connected to the mother station 200 is located at a short distance, the first and second signals to which the present invention is applied are applied. The present invention can be implemented in a state in which the transceivers 130 and 210 are not provided. In this case, only the transmission network exists between the local station 100 and the mother station 200. Of course, the transmission network used should be of a type having relatively low signal distortion, such as a general coaxial line. As described above, the transmission network is connected between the local station 100 and the mother station 200 to perform a communication function between each other at a short distance. Another embodiment of the present invention is described as follows. As shown in FIG. 4, another embodiment of the present invention amplifies and downconverts a signal received through the antenna 110. The RF processor 120 up-converts and amplifies the restored RF signal and radiates through the antenna, and amplifies and outputs the RF signal output from the above-described RF processor 120, and outputs a signal received from the mother station 200. RF signal for amplifying and outputting the amplified signal of the slave station 100 and the slave station 100 through the transmission network 100 including a booster 130a for amplifying and outputting the RF signal processor 120 to the RF signal processor 120. The linearity correction circuit unit 210a for correcting the distortion of the signal and the RF signal whose distortion is corrected in the linearity correction circuit unit 210a are processed as data in the form of packets and transmitted to the exchange apparatus 230, and the exchange apparatus 230. It consists of a mother station 200 composed of a digital processing unit 220 for converting the data in the form of a packet received from the RF signal to the linearity correction circuit unit 210a. Another embodiment of the present invention having the above configuration The booster 130a is provided in place of the first signal transceiver 130 and the linearity correction circuit 210a is provided in place of the second signal transceiver 210 to boost the signal output from the local station 100. Amplify the signal, transmit the amplified signal to the mother station 200, and also amplify the signal received from the mother station 200 through the booster 130a and output the amplified signal to the RF processor 120. At this time, the reason for amplifying the signal transmitted and received by the local station 100 through the booster 130a is to prevent the signal from being lost during the transmission and reception process. The linearity correction circuit unit 210a of the mother station 200 The signal transmitted to the local station 100 and the signal received at the local station 100 are output in the following blocks in a non-distorted state. Other descriptions are the same as described in the exemplary embodiment of the present invention, and will be omitted. do.

Therefore, as described above, the present invention can achieve several effects as follows.

First, a base station having the same size as a current DR repeater can be implemented. Of course, small sized base stations with call processing capacity, such as PIC0 base stations, have emerged, but since they have a digital processing part, there is a limit to reducing the size. By doing so, it is possible to minimize the size of the marks.

Second, if the signal transmission / reception part that compactly connects the RF processing part of the country and the digital processing part of the switching station through the transmission network to transmit and receive signals is connected directly behind the current antenna, or is formed integrally with the antenna. It is possible to implement a module, and when only a transmission network and a power supply are connected, there is an effect that one base station system is made.

Third, the power loss and noise figure caused by the feeder in the conventional method is not bad, there is an effect that the RF characteristics in the communication system is greatly improved.

Fourth, there is no need for a separate device for the management of the user, such as the roof or bare land of the building is a small or almost no need to rent.

Fifth, there is an effect that relocation and new construction can be made freely by coping with extreme RF environment change in urban area due to the expansion of buildings.

Claims (6)

In the transmission network expansion apparatus of a communication system in which a plurality of stations connected to one mother station through a transmission network to expand the service area of the mother station, The marks, Receives data in the form of compressed digital data through a transmission network, restores it to an RF signal, amplifies and upconverts the recovered RF signal, and radiates it through an antenna. Converts the RF signal transmitted from the terminal into data in the form of compressed digital data and transmits it to the mother station through the transmission network; The motherland, Converts packet data transmitted from the switching device into RF signal, converts the converted RF signal into compressed digital data data and transmits it to the local station through the transmission network, and compresses the compressed digital data type transmitted from the local station. Transmission network expansion device of a communication system, characterized in that to restore the data to the RF signal after processing the data in the form of a packet to the switching device. The method of claim 1, wherein the marks, An RF processor for amplifying and downconverting a signal received through the antenna, upconverting and amplifying the restored RF signal to radiate through the antenna; And The first signal converts the RF signal output from the RF processing unit into data in the form of compressed digital data and transmits it to the mother station, and restores the data in the compressed digital data form transmitted from the mother station to the RF signal and outputs the RF signal to the RF processor. Transmission network expansion device of a communication system, characterized in that the transmission and reception unit. The method of claim 1, wherein the home country, A second signal transmission for receiving data in the form of compressed digital data of the local station through a transmission network, restoring the data into an RF signal, converting the RF signal transmitted from the digital processing unit into data in the form of compressed digital data, and transmitting the data to the local station; Receiving unit; And The RF signal recovered by the second signal transmitter / receiver is processed into packet-type data and transmitted to the exchange apparatus, and the packet-type data received at the exchange apparatus is converted into an RF signal and transmitted to the second signal transmitter / receiver. Transmission network expansion device of a communication system, characterized in that consisting of a digital processing unit. The method of claim 2 or 3, wherein the first signal transmission and reception unit and the second signal transmission and reception unit, Signal compression / recovery unit having real-time large compression rate and transmission rate; And And a matching module for matching a local station and a mother station to a transmission network so as to transmit and receive signals between the base station and the switching center connected through the transmission network. The method of claim 1, wherein the transmission network, Transmission network extension device of a communication system, characterized in that the infrastructure network is all forms of data transmission in the form of wired or wireless network or local loop. delete