KR20100099628A - Apparatus for matching rf transceiver and repeater in mobile telecommunication system - Google Patents

Abstract

PURPOSE: An apparatus for matching an RF transceiver and a repeater in a mobile telecommunication system is provided to implement a cell plan of various format by converting a discontinued time share data pattern for link transmission into a continued time share data pattern. CONSTITUTION: Transmission processing units(205,206,207,208) copy discontinued time share data transmitted from a modem(100) to an RF(Radio Frequency) transceiver(400), and converts the data into continued time share data. Reception processing units(210,211,212,213) convert the discontinued time share data into continued time share data. The reception processing units transfer the converted discontinued time share data to the modem.

Description

A device for matching radio transceivers and repeaters in mobile communication systems {APPARATUS FOR MATCHING RF TRANSCEIVER AND REPEATER IN MOBILE TELECOMMUNICATION SYSTEM}

The present invention relates to a matching device of a mobile communication system, and more particularly, to an apparatus for matching a RF transceiver and a repeater.

Next-generation communication-related base station devices support various data rates in order to satisfy the needs of various operators and various frequency bands in modems and RF transceivers. For example, a WiMax base station device may be used in a modem or transceiver to provide various types of transmission rates, such as group 1 (11.2 MHz, 5.6 MHz, 2.8 MHz, 1.4 MHz), group 2 (8 MHz, 4 MHz, 2 MHz, 1 MHz), Group 3 (10MHz, 5MHz, 2.5MHz, 1.25MHz) and so on. The base station apparatus selects and processes the data occupancy time at different transmission speeds in the communication and interface between the modem and the RF transceiver.

Specifically, a base station apparatus (mounted in an RF transceiver) that supports a multi data rate will be described below.

Base station communication takes place between the modem and the digital RF transceiver.

The connection between the modem and the RF transceiver is via an optical cable (optical interface). As a component of the base station apparatus in the RF transceiver, SERDES (Serializer / Deserializer) has a function (Deserializion) that converts high-speed serial data into low-speed parallel data and high-speed parallel data. It has a function to convert serial data (Serializion). The uplink path of the base station apparatus includes a deserializer, a digital up converter (DUC), an RF up converter, a power amplifier (PA), and the like. The RF upconverter includes a digital-to-analog converter (DAC) and a high frequency phase locked loop (PLL) mixer for uplink transmission. The downlink path of the base station apparatus is composed of a low noise amplifier (LNA), an RF down converter, a digital down converter (DDC), a serializer, and the like. RF downconverters include low-frequency PLL mixers and analog-to-analog converters (DACs) for downlink transmission.

Looking at the operation of the base station apparatus, the signal transmitted from the modem through the optical cable (optical interface) is converted to a low speed parallel signal through SERDES (Deserializion). The deserialized uplink signal through SERDES is transmitted to the RF upconverter via the DUC. In an RF upconverter, a digital-analog converted signal (analog signal) is converted into a high frequency signal through a high frequency PLL mixer, amplified through a PA, and then propagated wirelessly. In the DUC, signal upsampling (interpolation process) and filtering are performed, and various data rates can be processed.

The downlink signal passes through the LNA and the RF downconverter. In the RF downconverter, a low-frequency PLL mixer converts an intermediate frequency analog signal, converts it to analog-to-digital, and then converts it to a relatively high speed digital sample. Filtered and downsampled via DDC (which entails a reduction process) is converted to a high speed serial signal via SERDES and sent to the modem via an optical cable (optical interface). do. The DDC performs downsampling and filtering of signals and can handle various data rates.

However, the base station apparatus cannot match the repeater. For example, for one transmission rate, in order for the base station apparatus and the repeater to be digitally combined, the base station apparatus and the repeater must be data in a continuous time occupied state. Since it is not considered, a repeater matching device that takes this into consideration is essential. Therefore, a repeater matching device is required separately for communication considering a repeater. In particular, such a device is more urgently needed in a WiMax / LTE system. For example, the WiMax system uses a time division duplexing (TDD) scheme and the LTE system can be selected from two types of time division duplexing (TDD) / frequency division duplexing (FDD). In CDMA or WCDMA system, since it is not TDD method, RF signals can be combined at the front / end stage during repeater matching.However, in WiMax / LTE system using TDD method, it is necessary to combine TDD Syn transmission and multiple frequencies to combine simple RF signals. There are many limitations, such as consolidating bands into one.

An object of the present invention is to provide an apparatus for matching radio transceivers and repeaters in mobile communication systems (especially WiMax / LTE systems, etc.).

According to an aspect of the present invention, an apparatus capable of connecting a repeater in communication between a modem and a transceiver, each of which is designed to handle multiple transmission rates in one piece of hardware, is disclosed. The device is provided between the modem and the RF transceiver / repeater, copies the discrete time occupied data transmitted from the modem to the RF transceiver, converts it into continuous time occupied data, and transmits it to the repeater, and the discontinuous received from the RF transceiver. The time occupancy data is converted into continuous time occupancy data, the converted continuous time occupancy data is combined with the continuous time occupancy data received from the repeater, and then converted into discontinuous time occupancy data and transmitted to the modem.

According to the RDCM of the present invention, there is an advantage in that it is possible to connect a repeater in communication between a modem and a transceiver, which are designed to process multiple transmission rates in one hardware. Intermediate bridge to connect other systems besides modem and RF transceiver through efficient signal conversion that converts discrete time-occupied data patterns for link transmission between two modules (modem, RF transceiver) into a continuous form and vice versa By doing so, various types of cell plans required by service providers are possible. In addition, repeater matching is possible in various frequency bands through different types of data format conversion.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

1 is a diagram illustrating a configuration of an apparatus for matching an RF transceiver and a repeater according to an embodiment of the present invention.

The apparatus (RDCM) 200 according to the present invention digitally combines the modem card 100, the digital RF transceiver 400, and the repeaters 300 and 500.

The connection between the modem card 100 and the RDCM 200 and the connection between the RDCM 200 and the digital RF transceiver 400 are made of optical cables (optical interfaces) 201 and 209.

SERDES (Serializer / Deserializer) 202, 208 converts high speed serial data into low speed parallel data (Deserializer) and converts low speed parallel data into high speed serial data (Serializer). The SERDES 202 receives high speed serial data from the modem card 100 via the optical interface 201, and the SERDES 208 converts the high speed serial data into a digital RF transceiver 400 via the optical interface 209. send. In addition, the SERDES 208 receives high-speed serial data from the digital RF transceiver 400 through the optical interface 209, and the SERDES 202 converts the high-speed serial data into a high-speed serial data through the optical interface 201 through a modem card ( 100).

The divider 203 copies an input signal on an uplink path and sends it to each output. The output includes a first transmission path for transmitting a signal to a repeater (relay receiver 300) and a second transmission path for transmitting a signal to the digital RF transceiver 400.

The delay block 204 applies a desired time delay to the signals of the first and second uplink paths. In addition, the delay unit 212 applies a desired time delay to the signals of the first and second downlink paths. The first reception path is a signal path for transmitting a signal from the digital RF transceiver 400 to the modem card 100, and the second reception path is a signal from the repeater (repeater transmitter 500). Signal path for transmission to the network. Here, the time delay is applied based on the distance between the modem card 100 and the RF transceiver 400 and the distance between the modem card 100 and the repeaters 300 and 500. That is, the distance between the repeaters 300 and 500 and the digital RF transceiver 400 varies according to a cell plan, and a processing delay variation occurs between each module (digital RF transceiver and repeater). For the modem, the two modules (digital RF transceiver and repeater) should be recognized as if the distances are the same, so the module closest to the modem operates with an internal delay than the remote module.

The signal change units 205 and 213 convert a data format of a discontinued occupied state into a data format of a continuous occupied state. In addition, the signal converter 215 converts a data format of a continuous occupied state into a data format of a discontinued occupied state. The data occupancy state can be a time that data occupies and a time that is not. The discontinuous pattern means that the time occupied by the data is discontinuous, and the continuous pattern means that the time occupied by the data is continuous. The signal converters 205 and 215 convert continuous data into non-continuous data or convert non-continuous data into continuous data based on the data processing format of the modem 100 and the digital RF transceiver 400. Since the data formats of the modem 100 and the digital RF transceiver 400 vary according to the use frequency, the signal converter 213 converts these various formats into data having a predetermined rate and processes them. In FIG. 2, "2a" and "2c" are discrete data formats between the modem 100 and the digital RF transceiver 400, and "2b" represents a constant continuous data sampling format in the corresponding frequency band.

The Digital Up Converter (DUC) 206 performs upsampling of data (which involves an interpolation process) and filtering, and performs various transmission rates (eg, WiMax). In this case, Group 1 (11.2MHz, 5.6MHz, 2.8MHz, 1.4MHz), Group 2 (8MHz, 4MHz, 2MHz, 1MHz), Group 3 (10MHz, 5MHz, 2.5MHz, 1.25MHz, etc.) are processed.

A digital up converter (DUC) 211 performs filtering and downsampling (in this case, a reduction process), and processes various data rates.

The transmission intermediate frequency (Tx_IF) converter 207 is a digital-to-analog converter (DAC), a high frequency phase locked loop (MIXer), a power amplifier (PA) for uplink transmission. And converts the digital signal into an analog signal (DAC), converts the digital signal into an intermediate frequency (IF) signal to be transmitted to the repeater (receiver 300), and amplifies and transmits the signal to the repeater 300. .

The reception intermediate frequency (Rx_IF) converter 210 includes a low noise amplifier (LNA), a low frequency PLL mixer, an analog-to-digital converter (ADC), and the like for downlink transmission. The analog signal transmitted from the repeater transmitter 500 is low noise amplified and converted into an intermediate frequency signal and then converted into a digital signal (ADC).

The combiner 214 digitally combines the signal received at the digital RF transceiver 400 and the signal received at the repeater (relay transmitter 500) on the downlink path.

In summary, the RDCM 200 is a device for matching the RF transceiver 400 and the repeaters 300 and 500, and is provided between the modem 100 and the digital RF transceiver 400 / repeater 300 and 500, and the modem 100. A transmission path for copying the discontinuous time occupancy data transmitted from the digital RF transceiver 400 to the repeater 300 after converting the continuous time occupancy data into the continuous time occupancy data, and the discontinuous received from the digital RF transceiver 400. Converts the time occupancy data into continuous time occupancy data, combines the converted continuous time occupancy data with the continuous time occupancy data received from the repeater 500, and then converts the time occupancy data into discontinuous time occupancy data to the modem 100. It contains the receiving path for delivery.

On the transmission path, a serializer of the SERDES 202 which receives discontinuous high speed serial data from the modem 100 via the optical interface 201 and converts the speed into discontinuous low speed parallel data, and a discontinuous low speed speed converted. And a distribution unit 203 for copying the parallel data, and outputting the parallel data to the first transmission path for signal transmission to the repeater 300 and the second transmission path for signal transmission to the digital RF transceiver 400, respectively. A delay unit 204 for delaying discontinuous low-speed parallel data according to distance (distance to repeater and distance to digital RF transceiver) and processing delay (internal processing delay of repeater / digital RF transceiver module) on the second transmission path And first transmission processing means for transmitting a signal (data of continuous time occupancy state) to the repeater 300 via the first transmission path, and digitally through the second transmission path. And second transmission processing means for transmitting a signal (data in a discontinuous time occupancy state) to the RF transceiver 400.

Here, the first transmission processing means includes a signal converter 205 for converting the discontinuous low speed parallel data delayed by the delay unit 204 into continuous low speed parallel data on the first transmission path, and the first transmission path. In this example, the digital up-converter 206 for upsampling and filtering the continuous low-speed parallel data converted by the signal converter 205 and the continuous low-speed parallel data upsampled and filtered by the up-converter 206 After converting to an analog signal, and includes a transmission intermediate frequency conversion unit 207 for converting the converted continuous low-speed parallel analog signal to a high frequency signal through a high frequency PLL mixer to transmit to the repeater 300. The second transmission processing means converts the discontinuous low speed parallel data delayed by the delay unit 204 into high speed serial data on the second transmission path and transmits the converted speed to the digital RF transceiver 400 through the optical interface 209. A serializer of SERDES 208 is provided. The delay units 204 on the first and second transmission paths may be the same or may be provided for each transmission path.

On the reception path, first reception processing means for receiving a signal (data in a discontinuous time occupancy state) from the RF transceiver 400 via the first reception path, and a signal through the second reception path from the repeater 500 ( A combiner for combining continuous second low-speed processing means for receiving continuous time-occupied data) and outputting continuous low-speed parallel data by combining signals of the first and second receiving paths (discontinuous low-speed parallel data); 214, the signal converter 215 for converting continuous low speed parallel data into discontinuous low speed parallel data, and the discontinuous low speed parallel data converted by the signal converter 215 as high speed serial data. It includes a serializer of the SERDES (202) for speed conversion and transmission to the modem 100 via the optical interface 201.

Here, the first receiving processing means receives SERDES (SERDES) that receives discontinuous high speed serial data from the RF transceiver 400 through the optical interface 209 on the first receiving path and converts the speed into discontinuous low speed parallel data. 208) and a discontinuous low speed parallel on the first receive path, speed converted according to (distance to repeater and distance to digital RF transceiver) and processing delay (internal processing delay of repeater / digital RF transceiver module). A delay unit 212 for delaying data and a signal converter 213 for converting the discontinuous low-speed parallel data delayed by the delay unit 212 into continuous low-speed parallel data on the first reception path. . The second receiving processing means may include: a receiving intermediate frequency converting unit 210 for converting a signal received from the repeater 500 into a medium frequency analog signal through a low frequency PLL mixer on a second receiving path and then converting the signal into a digital signal; A digital down-converter 211 for filtering and downsampling discontinuous low-speed parallel data converted into a digital signal on a second reception path, and a discontinuously filtered and downsampled discontinuity according to a distance and a processing delay on the first reception path And a delay unit 212 for delaying low-speed parallel data. The delay unit 212 on the first and second reception paths may be the same or may be provided for each reception path.

Looking at the operation of the device (RDCM) (200) having the configuration as described above is as follows.

The uplink path includes a modem card 100, an RDCM 200, a digital RF transceiver 400, and a repeater receiver 300.

The RDCM 200 copies the discontinued data received from the modem card 100 in a predetermined path for transmission to the relay 300 and the digital RF transceiver 400, respectively. Specifically, the signal (discontinuous high speed serial data) transmitted from the modem card 100 through the optical interface 201 is converted into a low speed parallel signal by the deserializer of the SERDES 202 and deserialized through the SERDES 202. The uplink signal (discontinuous low-speed parallel signal) is transmitted to the distribution unit 203, and transmits the signal to the RF transceiver 400 and the first transmission path for transmitting the signal from the distribution unit 203 to the repeater 300. Copied to the second transmission path.

The signals of the first and second transmission paths are delayed differently based on the distance between the modem card 100 and the RF transceiver 400 and the distance between the modem card 100 and the repeater 300 in the delay unit 204. . That is, since the distance between the RDCM 200 and the repeater 300 and the distance between the RDCM 200 and the digital RF transceiver 400 are different, and processing delays inside each module (digital RF transceiver, repeater) are different, delays to match them are delayed. The unit 204 applies a delay to the first transmission path and the second transmission path.

The signal conversion unit 205 has a discontinued time occupancy state in which the data pattern transmitted from the modem card 100 is discontinued (2a in FIG. 2), and thus the first transmission path transmitted from the delay unit 204. A continuous low speed parallel signal of the phase is converted into a continuous occupied data pattern (2b in FIG. 2) to be sent to the repeater 300. The 'consecutive low-speed parallel signal (uplink signal) on the first transmission path' converted by the signal converter 205 is transmitted to the transmission intermediate frequency converter 207 via the digital up-converter (DUC) 206. do. At this time, the digital up-converter 206 performs upsampling (which involves an interpolation process) and filtering of the signal, and processes various transmission rates. The transmission intermediate frequency converter 207 converts the continuous low-speed parallel digital signal upsampled and filtered by the digital up-converter 206 into an analog signal through a digital-to-analog converter (DAC), and then converts the converted analog signal ( A continuous low speed parallel analog signal) is converted into a high frequency signal through a high frequency PLL mixer, amplified through a power amplifier (PA) (not shown), and transmitted to the repeater 300.

In addition, the discontinuous low-speed parallel signal on the second transmission path transmitted from the delay unit 204 is converted into high-speed serial data in the serializer of the SERDES 208 to the digital RF transceiver 400 through the optical interface 209. Is sent.

The RDCM 200 converts the discontinuous data pattern transmitted from the modem card 100 on the first transmission path into a continuous data pattern and transmits the same to the repeater 300, and transmits the transmission from the modem card 100 on the second transmission path. The discontinuous data pattern is transmitted to the digital RF transceiver 400 without converting the discontinuous data pattern into a continuous data pattern.

The downlink path includes a digital RF transceiver 400 / repeater transmitter 500, an RDCM 200, and a modem card 100.

The RDCM 200 digitally combines the discontinuous data pattern received from the digital RF transceiver 400 and the continuous data pattern received from the repeater 500, and then converts the discontinuous data pattern into a discontinuous data pattern, thereby converting the modem card through the optical interface 201. Send to 100.

The reception path of the RDCM 200 transmits the first reception path for transmitting the signal received from the digital RF transceiver 400 to the modem card 100 and the signal received from the repeater 500 to the modem card 100. It is divided into a second reception path for.

The signal (discontinuous high speed serial data) transmitted from the digital RF transceiver 400 through the optical interface 209 on the first reception path is converted into a low speed parallel signal by the deserializer of the SERDES 208, and the SERDES 208 is converted into a low speed parallel signal. The deserialized downlink signal (discontinuous low speed parallel signal) is transmitted to the delay unit 212.

The downlink signal (continuous data pattern) received from the repeater 500 on the second reception path passes through the reception intermediate frequency converter 210 through an LNA (not shown). The receiving intermediate frequency converter 210 converts the intermediate frequency analog signal through a low frequency PLL mixer, converts the analog frequency into a digital sample of a relatively high speed, and transmits the analog frequency to a digital downconverter 211. The filtered and downsampled signal (which entails a reduction process) is transmitted to the delay unit 212 through the digital down-conversion unit (DDC) 211.

The signals of the first and second reception paths are delayed differently based on the distance between the modem card 100 and the RF transceiver 400 and the distance between the modem card 100 and the repeater 500 in the delay unit 212. That is, since the distance between the RDCM 200 and the repeater 500 and the distance between the RDCM 200 and the digital RF transceiver 400 are different, and processing delays inside each module (digital RF transceiver and repeater) are different, delays to match them are delayed. The unit 212 applies a delay to the first reception path and the second reception path.

Since the data pattern transmitted from the digital RF transceiver 400 on the first reception path is in a discontinued time occupation state (2a in FIG. 2), the discontinuous data pattern and the repeater 500 received from the digital RF transceiver 400 In order to digitally combine the continuous data patterns received from the combiner 214, the signal converter 213 outputs a discontinuous low-speed parallel signal on the first receiving path transmitted from the delay unit 212. To a continuous occupied data pattern (2b in FIG. 2). The 'consecutive low speed parallel signal (downlink signal) on the first reception path' converted by the signal converter 213 is transmitted to the combiner 214.

The combiner 214 is transmitted from the digital RF transceiver 400 and the second data transmitted from the repeater 500 and the continuous data pattern (low speed parallel signal) on the first reception path converted by the signal converter 213. Digitally combine successive data patterns (low-speed parallel signals) on the path.

The signal converter 215 discontinued data (2c in FIG. 2) to transmit a signal of a continuous data pattern (2b in FIG. 2) coupled by the combiner 214 to the modem card 100. Convert to

The discontinuous low speed parallel data converted by the signal converter 215 is converted into discontinuous high speed serial data in the serializer of the SERDES 202 and transmitted to the modem card 100 through the optical interface 201.

Although the present invention has been described in connection with some embodiments thereof, it should be understood that various changes and modifications may be made therein without departing from the spirit and scope of the invention as understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 is a diagram showing the configuration of an apparatus for RF transceiver and relay matching according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating a speed conversion process in the signal converter of FIG. 1. FIG.

* Explanation of symbols for the main parts of the drawings

100: modem card 200: matching device

201,209: optical interface 202,208: SERDES

203: distribution unit 204, 212: delay unit

205, 213, 215: signal converter 206: digital up-converter (DUC)

207: transmission intermediate frequency conversion unit 210: reception intermediate frequency conversion unit

211: digital down-conversion unit (DDC) 214: coupling unit

300: repeater receiver 400: RF transceiver

500: repeater transmitter

Claims (8)

In the apparatus for matching a repeater of a mobile communication system, It is provided between the modem and the RF transceiver / repeater, Transmission processing means for copying discontinuous time occupancy data transmitted from the modem to the RF transceiver, converting the continuous time occupancy data into continuous time occupancy data, and transmitting the same to the repeater; And Convert the discontinuous time occupancy data received from the RF transceiver into continuous time occupancy data, combine the converted continuous time occupancy data with the continuous time occupancy data received from the repeater, and then convert to discontinuous time occupancy data. And receiving processing means for delivering to the modem. The method of claim 1, And the transmission processing means and the reception processing means each have a delay unit for signal delay since the distance from the RF transceiver and the repeater are different and the processing delays of the RF transceiver and the repeater are different. The method of claim 2, The transmission processing means, A deserializer of SERDES that receives discontinuous high speed serial data from the modem through a first optical interface and converts the speed into discontinuous low speed parallel data; A distribution unit which copies the speed-converted discontinuous low-speed parallel data and outputs the first transmission path for signal transmission to a repeater and the second transmission path for signal transmission to an RF transceiver; A delay unit configured to delay the discontinuous low-speed parallel data according to the distance and the processing delay on the first and second transmission paths; First transmission means for transmitting a signal to the repeater through the first transmission path; And And second transmission means for transmitting a signal to the RF transceiver via the second transmission path. The method of claim 3, The first transmission means, A signal conversion unit converting the discontinuous low speed parallel data delayed by the delay unit into continuous low speed parallel data on the first transmission path; An up-converter configured to upsample and filter continuous low-speed parallel data converted by the signal converter on the first transmission path; And The up-conversion unit converts the continuous low-speed parallel data filtered and upsampled and filtered into an analog signal, and then converts the converted continuous low-speed parallel analog signal into a high-frequency signal through a high-frequency PLL mixer and transmits the same to the repeater. Device comprising an intermediate frequency converter. The method of claim 3, The second transmission means, And a serializer of SERDES on the second transmission path, converting the discontinuous low-speed parallel data delayed by the delay unit into high-speed serial data and transmitting the high-speed serial data to the digital RF transceiver through a second optical interface. The method of claim 2, The receiving processing means, First receiving means for receiving a signal from the RF transceiver through a first receiving path; Second receiving means for receiving a signal from the repeater through a second receiving path; A combiner configured to combine the signals of the first and second reception paths (discontinuous low speed parallel data) to output continuous low speed parallel data; A first signal converter converting the continuous low speed parallel data into discontinuous low speed parallel data; And And a serializer of SERDES which converts the discontinuous low speed parallel data converted by the first signal converter into high speed serial data and transmits the converted speed to the modem through a first optical interface. The method of claim 6, The first receiving means, A deserializer of SERDES that receives discontinuous high speed serial data from the RF transceiver via the second optical interface on the first reception path and converts the discontinuous high speed serial data into discontinuous low speed parallel data; A delay unit configured to delay the speed-converted discontinuous low speed parallel data according to the distance and the processing delay on the first reception path; And And a second signal converter configured to convert discontinuous low speed parallel data delayed by the delay unit into continuous low speed parallel data on the first reception path. The method of claim 6, The second receiving means, A reception intermediate frequency converting unit converting the signal received from the repeater on the second reception path into an intermediate frequency analog signal through a low frequency PLL mixer and then converting the signal into a digital signal; A down converter configured to filter and downsample discontinuous low-speed parallel data converted into the digital signal on the second reception path; And And a delay unit configured to delay the filtered and downsampled discontinuous low speed parallel data according to the distance and processing delay on the first reception path.

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