KR20100021866A - Remote optic unit of digital repeater - Google Patents

Abstract

PURPOSE: A digital optical unit of a digital repeater is provided to prevent the deterioration of the property of a signal generated by adopting a digital pre-distortion manner. CONSTITUTION: A first frequency converting unit(360) performs a frequency conversion to place a channel-filtered signal at the central portion of a DPD(Digital Pre-Distortion) engine bandwidth, and a CFR(Crest Factor Reduction) unit(370) performs the CFR process of an outputted signal outputted from a first frequency converting unit. The DPD engine performs the DPD processing of an output signal from the CFR unit. A second frequency converting unit up-converts or down-converts the signal outputted form the DPD engine as much as the frequency in the reverse direction of the frequency that is converted in the first frequency converting unit.

Description

Remote optical unit of digital optical repeater {REMOTE OPTIC UNIT OF DIGITAL REPEATER}

The present invention relates to a remote optical unit of a digital optical relay device, and more particularly, to prevent the characteristic value of a signal generated by adopting a digital predistortion method to the remote optical unit of a digital optical relay device, In other words, the digital predistortion technology solves the problems caused by applying the digital predistortion technology, which is completely compatible with the existing main hub unit, while reducing power consumption generated by the remote optical unit. The remote optical unit of the digital optical relay device, maximizing the advantages of the.

In general, a digital optical relay device includes a main hub unit (MHU) and a remote optical unit (ROU). In the case of the remote optical unit used in the digital optical relay device, a power amplifier for processing a high power transmission signal has been used.

Currently, power amplifiers used in almost all remote optical units use a feed-forward multi-carrier power amplifier (MCPA), which has a complicated structure. Compared with other methods, the degree of linearization is very good and has broadband characteristics. However, this feed-forward multi-channel power amplifier had a efficiency of only 7-8%, and had a problem of dissipating most of its power as heat.

Since the conventional remote optical unit has a large amount of inefficient heat generation, a forced cooling method is used rather than a natural cooling method. In the forced cooling method, since the fan is used outside the enclosure of the remote optical unit, a problem such as noise occurs, and the inconvenience of having to frequently perform the A / S of the fan occurs. In order to eliminate such inconvenience, a natural cooling method should be applied, which has a limitation in the existing remote optical unit using the feed forward method.

Due to this technical demand, recent attempts have been made to introduce digital predistortion into digital optical relay devices. Examples thereof include Korean Patent Registration No. 10-0712594 and Korean Patent Registration No. 10-0720743.

First, in Korean Patent Registration No. 10-0720743, a digital optical relay including a main hub unit for wireless communication with a base station, and a remote optical unit connected to the main hub unit via an optical cable and wirelessly communicating with a subscriber station. A system comprising: a signal processing module for processing a signal received from the main hub unit and outputting the signal in the form of digital baseband I / Q parallel data; And a digital predistortion module configured to perform digital predistortion processing on the digital baseband I / Q parallel data from the signal processing module and to amplify the high output and output the duplexer to the subscriber station. The distortion module comprises: an input FPGA unit for serializing the input digital baseband I / Q parallel data; A digital predistorter which detects an RF signal output to the duplexer and compares the signal fed back to the output signal of the input FPGA unit, and randomly distorts the digital predistorter to improve linearity; A down converter for down frequency converting the RF signal output to the duplexer; A digital filter for digital low pass filtering the output signal of the down converter; A digital processor for sampling the digital filtered signal and outputting the sampled digital signal to the digital predistorter as a feedback signal; A digital / analog converter for converting the digital output signal of the digital predistorter into an analog signal; An up converter for upconverting the frequency of the output signal of the digital / analog converter to an RF frequency; Disclosed is a digital optical relay system using digital predistortion, comprising a high power amplifying unit for high power amplifying an output signal of the upconverter and outputting the amplified signal to the duplexer.

Next, the Republic of Korea Patent No. 10-0712594, Digital hub including a main hub unit for wireless communication with the base station, the remote optical unit is connected to the main hub unit via an optical cable and wireless communication with the subscriber station In the optical relay system, the remote optical unit is composed of a ROU integration module, a duplexer and an LNA / downconversion module, wherein the ROU integration module converts a forward optical signal received through an optical cable into an electrical signal and the following FPGA. The digital optical conversion unit converts the reverse electrical signal from the unit into an optical signal and transmits the optical signal to the optical cable, and serially outputs the forward electrical signal from the digital optical conversion unit, and processes the reverse signal from the following ADC unit. To transmit the linearity between the FPGA unit and the signal from the FPGA unit. A pre-distortion processing unit for distorting and outputting the harmonic signal, a digital / analog converter for converting the output signal of the pre-distortion processing unit into an analog signal, and an up-converter for up-converting the output signal of the digital / analog conversion unit; A digital power converter comprising a high power amplifier configured to high power amplify an output of an upconverter and an analog / digital converter configured to convert a reverse signal from the LNA / downconverter module into a digital signal and output the digital signal to the FPGA; Disclosed is a digital optical relay system using distortion.

The power consumption is reduced in the above two conventional techniques, ie, a technique in which digital predistortion is applied, in order to satisfy the transmission output characteristic required by the digital optical relay in the feedforward method, the transistor is moved in the power amplifier main path. This is because only the transistor for the main path and the transistor for the error path must be used, but in the digital predistortion method. As the number of transistors is reduced, the power consumption can be reduced.

However, the above two patents, which simply adopt the known digital predistortion method in the digital optical relay device, have the effect of reducing the heat generation as compared to the conventional feed forward method, but the digital optical relay adopting the digital predistortion method. Test results of the device found that the characteristic value was worse than the feed forward method.

The present invention has been made to solve the above problems, and the digital optical relay device which can prevent the deterioration of the characteristic value of the signal generated by adopting the digital predistortion method to the remote optical unit of the digital optical relay device. To provide a remote optical unit of the object.

In addition, it is another object to provide a remote optical unit of the digital optical relay device that is significantly reduced the power consumption of the remote optical unit, and compatible with the main hub unit that has been developed and used in the field.

In other words, while being compatible with the main hub unit that has been developed, it solves various problems in applying the digital predistortion technique used to reduce the power consumption in the remote optical unit, thereby improving the advantages of the digital predistortion technique. It is an object of the present invention to maximize.

In order to achieve the above object, according to an embodiment of the present invention, the main hub unit (Main Hub Unit) for wireless communication with the base station; A remote optical unit of a digital optical relay device, comprising a remote optical unit connected to the main hub unit via an optical cable and performing wireless communication with a subscriber station, comprising: a digital optical signal received from the main hub unit An optical module for converting a digital electrical signal into a digital electrical signal, converting a digital electrical signal input from a framer / reframer below into a digital optical signal, and transmitting the digital electrical signal to the main hub unit; Framer / Reframer; An FA type information detector for detecting the type information of the FA of the digital signal through power detection of the FA of the digital signal input from the framer / reframer; A channel filter unit performing channel filtering using a digital channel filter corresponding to the type information of the FA detected by the FA type information detector; A first frequency converter converting the channel filtered signal into a frequency center so as to position the signal at a center of a bandwidth of a digital pre-distortion unit; A CFR (Crest Factor Reduction) unit for performing CFR processing on the signal output from the frequency converter; And a digital predistorter configured to receive the output signal of the CFR unit and perform digital predistortion processing.

A frequency up-conversion or frequency for the signal output from the digital predistorter in a direction opposite to the frequency converted by the first frequency converter to frequency-convert the signal to the center portion of the bandwidth of the digital predistorter. A second frequency converter configured to down-convert,

With power amplifier,

It provides a remote optical unit of a digital optical relay system, characterized in that it comprises a filter module consisting of an integrated duplex, a band pass filter (BPF) and an arrester.

In addition, the FA is composed of FA 1, FA 2, FA 3 and FA 4, the type information of the FA, 16 kinds determined depending on the presence or absence of the FA 1, the FA 2, the FA 3 and the FA 4 It is preferred to be one of the cases.

In addition, the CFR unit, it is preferable to apply a CFR factor corresponding to the type information of the FA detected through the FA type information detection unit.

In addition, the channel filter unit may perform channel filtering to improve Adjacent Channel Leakage Ratio (ACLR) using a digital channel filter corresponding to the type information of the FA detected by the FA type information detector. Done.

First, according to the digital optical relay device according to an embodiment of the present invention, by applying the digital predistortion technology it is possible to improve the heat problem, which is a chronic problem of the digital optical relay device.

Secondly, the same digital predistortion technology is used as in the two patents mentioned in the background art, but different from the two patents mentioned in the background art, while using a power amplifier that uses less power, the registered patent Compared to the two cases, it is possible to prevent the deterioration of the characteristic value of the signal.

This is because in the prior art using a digital predistortion technique, a power amplifier with a high power consumption is used to prevent deterioration of signal characteristics. Therefore, in order to prevent the deterioration of signal characteristics and reduce the amount of heat generated, the FA type information detection unit uses the result of the FA type information detection unit in order to improve the characteristics of the adjacent channel leakage facilities in the previous step of the digital predistorter 380. By inputting a signal to the digital channel filter, the system specification is satisfied even when a power amplifier with low power consumption is used.

Third, unlike the prior art, in order to maximize the performance of the digital predistorter 380 in the first frequency converter 360, the digital predistorter 380 is used by using the result of the FA type information detector 340. The frequency is up-converted or down-converted to position the signal at the center of the bandwidth. Through this, it is possible to make the best use of the performance of the digital predistorter 380, and even if the low-cost digital predistorter is used, the same effect can be obtained.

Fourth, by reducing the PAPR of the signal using the CFR technology to increase the efficiency of the power amplifier, it is possible to increase the output of the system by using a power amplifier that uses less power consumption. Naturally, since a power amplifier using less power consumption is used, the amount of heat generated by the remote optical unit 200 can be further reduced by placing the CFR unit in front of the digital predistorter 380.

Fifth, the CFR unit has an effect of improving the performance of the remote optical unit by applying a CFR factor corresponding to the detected FA type information using a result of the FA type information detection unit 340 according to a situation.

Sixth, in the present invention, in order to improve the efficiency, unlike the existing remote optical unit 200, the duplexer (Duplexer) and the band pass filter is bundled with the filter module 300, and the arrester is built in the filter module, each configuration The method of increasing the output is applied by reducing the signal loss caused by the cable connection between the two. When the signal loss is reduced in this way, the output characteristics of the system can be satisfied without increasing the output of the power amplifier, resulting in an effect of increasing efficiency.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

FIG. 1 is a block diagram schematically illustrating a configuration of a digital optical relay apparatus according to an embodiment of the present invention, and FIG. 2 is a signal processing unit of a remote optical unit of a digital optical relay apparatus according to an embodiment of the present invention. 210 is a block diagram illustrating the configuration of the present invention in more detail. FIG. 3 is a diagram illustrating a field allocation (FA) used in a digital optical relay device according to an embodiment of the present invention. FIG. FIG. 5 is a diagram illustrating an example in which there are FA1 and FA3 among the types of FAs described, and FIG. 5 illustrates a conversion in the first frequency converter 350 when there are types of FAs illustrated in FIG. 4, that is, FA1 and FA3. It is a figure which shows the example of the up conversion.

Hereinafter, the present invention will be described with reference to FIGS. 1 to 5.

First, referring to FIG. 1, a digital optical relay device is basically connected to a main hub unit 100 that performs wireless communication with a base station, a main hub unit 100 through an optical cable, and is connected to a subscriber terminal ( And a remote hub unit (200) for wireless communication with each other. In such a digital optical relay apparatus, the present invention is applied to a digital optical relay apparatus already installed in the field, as well as replacing only a remote optical unit having a very poor heat generation efficiency while using the main hub unit as it is. It covers the case where the main hub unit and the remote optical unit are newly installed or replaced at the same time.

In FIG. 1, the configuration of the main hub unit 100, that is, the down converter 110, the up converters 120 and 130, the signal processing unit 140 of the main hub unit, the optical module 150 of the main hub unit, and the controller The 160 and the power supply 170 are used in the same manner as in the prior art, and thus description thereof will be omitted.

Referring to FIG. 2, the optical module 220 converts a digital optical signal received from the main hub unit 100 through an optical cable into a digital electrical signal and inputs it from the framer / reframer 330. The digital electrical signal is converted into a digital optical signal and transmitted to the main hub unit through an optical cable.

Next, the framer / reframer 330 uses a generally known framing and reframing technique.

Next, the FA type information detector 340 receives the type information of the FA of the input digital signal through power detection of the FA (Field Allocation) of the digital signal input from the framer / reframer 330. It is composition to grasp.

As shown in Fig. 3, the FA type is calculated by counting the number of cases where FA1, FA2, FA3, and FA4 are present and nonexistent. For example, as shown in FIG. 4, when FA1 and FA3 are present, the state of the signal is represented in the frequency domain. Such FA type information is detected by the FA type information detection unit 340 through power detection.

Next, the channel filter 350 performs channel filtering using a digital channel filter corresponding to the type information of the FA detected by the FA type information detector 340 described above.

As described above, in the case of the two patents described in the background art, in order to simply reduce the amount of heat generated by the existing remote optical unit, a method of simply inputting the signal transmitted to the remote optical unit directly to the digital predistortion engine is adopted. However, in this case, the characteristics of the signal are poor, and compared with the prior art which does not use the digital predistortion engine, a problem occurs such as using a power amplifier that consumes more power to produce the same characteristic value.

In order to solve the above problems and to be able to use the signal processed by the signal processing unit of the existing main hub unit as it is, in the present invention, adjacent channel leak facilities (ACLR: Adjacent) which is one of the important items in the digital predistortion method Channel filter unit 350 using the FA type information detector 340 and the digital channel filter corresponding to the FA type information detected by the FA type information detector 340 so as to satisfy the channel leakage ratio characteristic. ). At this time, the FA type information is automatically detected and the channel filter is automatically selected to maximize the adjacent channel leakage ratio performance. As a result, by using a power amplifier with low power consumption, it is possible to reduce the amount of heat generated and to prevent deterioration of characteristic values of the signal.

Next, the first frequency converter is configured to perform frequency conversion on the channel-filtered signal so that the signal is positioned at the center of the bandwidth of the digital pre-distortion unit.

Adopting such a first frequency converter 350 is a channel filter using a digital channel filter corresponding to the FA type information detector 340 and the FA type information detected by the FA type information detector 340 described above. This is to maximize the performance of the digital predistorter 380 in addition to the unit 350 technology.

By using the automatic detection function of the FA type information of the FA type information detector 340 described above, a frequency shifting technique is used to position the signal to the center of the bandwidth of the digital predistorter 380. In general, digital predistortion techniques are constrained by the bandwidth of the signal. Although it must handle several times the bandwidth of the signal to be serviced, the digital predistortion performance is properly implemented.

In the present invention, a method of shifting the frequency of a signal has been invented in order to utilize the bandwidth more efficiently. When the bandwidth to be serviced is 20 MHz, the bandwidth of the digital predistorter 380 becomes 100 MHz in consideration of the fifth-order IMD (Inter-Modulation Distortion) component.

In this case, when a service signal having a 5 MHz bandwidth is biased at one end of the 20 MHz bandwidth, only 85 MHz of the 100 MHz digital bandwidth is used. In this case, if the service signal of 5MHz bandwidth is brought to the center of 20MHz, the gain of 15MHz bandwidth is obtained compared to the bias at one end.

That is, by using all of the bandwidth of the 100MHz digital predistorter 380 it is possible to maximize the performance of the digital predistorter 380. In this way, the Tx Up convertor 230 and the Tx Down convertor 240 behind the digital predistorter 380 (the two configurations of the present invention are output from the digital predistorter 380). The frequency up-conversion or frequency-down-conversion of the signal by the frequency in the opposite direction of the frequency converted by the first frequency converter 360 to frequency-convert the signal to the center of the bandwidth of the digital predistorter 380. In the second frequency conversion unit), it is invented to return to the frequency of the first input signal by up-converting or down-covering in the opposite frequency direction as the original signal is moved to send to the center.

In addition, according to the type of FA type information input, the first frequency converter 360 automatically shifts the frequency based on the type information of the FA detected by the FA type information detector 340. .

이며, 디지털 전치 왜곡부(380)의 대역폭의 정중앙 주파수가

인 경우, a/2만큼 주파수 업 컨버전을 제 1 주파수 변환부(360)에서 하게 된다. For example, as shown in FIG. 5, the median value when FA1 and FA3 are present is

The center frequency of the bandwidth of the digital predistorter 380 is

In this case, the frequency up-conversion is performed by the first frequency converter 360 by a / 2.

Next, the CFR (Crest Factor Reduction) unit 370 performs CFR processing on the signal output from the first frequency converter 360. In this case, the signal input through the first frequency converter 360 is clipped based on a predetermined level to provide a clipped signal.

Through such a CFR unit 370, it is possible to increase the efficiency of the power amplifier 250. Because, by using the CFR technology to reduce the Peak Power to Average Power Ratio (PAPR) of the signal, the power amplifier 250 can be used with less power consumption as well as to increase the output efficiency of the system.

The CFR unit 370 used in the present invention is in the form of reducing the overall PAPR of the input signal. At this time, the CFR factor was automatically changed according to the case of FA input using the FA type information input to maximize the function of the CFR unit 370. For example, the CFR factor value according to the input signal of 4FA (when 4 FAs) and 2FA (when FA1 is 2, for example, when FA1 and FA3 are input as shown in FIG. 4). The CFR factor is separately stored for the input signal, and according to the detection of the FA type information detector 340, that is, according to the change of the input signal, the stored value is retrieved and set according to the situation at that time. do.

Next, the digital predistorter 380 receives the output signal of the CFR unit 370 and performs digital predistortion processing. Since this uses a digital predistortion technique known in the same manner as the prior art, the description thereof will be omitted.

As described above, the signal processing unit 210 of the present invention, the optical module 220; Framer / Reframer 330; An FA type information detector 340; A channel filter unit 350; A first frequency converter 360; CFR unit 370; A digital predistorter 380; And a DAC 390 and ADCs 440, 410, and 420.

Next, in addition to the signal processing unit 220, the remote optical unit 200 is configured to adjust the bandwidth of the digital predistorter 380 in the first frequency converter 360 to the signal output from the digital predistorter 380. A second frequency converter which up-converts or down-converts the frequency by the frequency in the direction opposite to the frequency converted to frequency-convert the signal to the center part, the power amplifier 250, the filter module 300, and the antenna ( 310, 320).

Here, the filter module 300 is composed of a duplex, a band pass filter (BPF) and an arrester. Unlike the conventional remote optical unit 200, in order to improve the efficiency, the duplexer and the band pass filter are bundled with the filter module 300, and the arrester is built in the filter module so that the signal by the cable connection between the components By reducing the loss, we apply a method to increase the output. When the signal loss is reduced in this way, the output characteristics of the system can be satisfied without increasing the power amplifier output. As a result, the efficiency can be increased.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications, changes and variations are possible within the scope of the claims to be described.

1 is a block diagram schematically illustrating a configuration of a digital optical relay apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating in more detail the configuration of the signal processor 210 among the remote optical units of the digital optical relay device according to an exemplary embodiment of the present invention.

FIG. 3 is a diagram illustrating Field Allocation (FA) used in a digital optical relay according to an embodiment of the present invention.

4 is a diagram illustrating an example in which there are FA1 and FA3 among the types of FA described in FIG. 3.

FIG. 5 is a diagram illustrating an example of up-conversion converted by the first frequency converter 350 when there are types of FAs illustrated in FIG. 4, that is, FA1 and FA3.

<Explanation of symbols for the main parts of the drawings>

100 Main Hub Unit 110 Down Converter

120, 130 Up Converter 140 Signal Processing Unit of Main Hub Unit

150 Optical Modules in the Main Hub Unit

160 Controller 170 Power Supply

200 Remote Optical Unit 210 Signal Processing Unit of Remote Optical Unit

220 Optical module of remote optical unit 240 Forward-side up converter

250 Forward Side Downcoverer 250 Power Amplifier

260, 265 Reverse Side Down Converter 270, 275 Low Noise Amplifier

280 Controller 290 Power Supply

300 filter module 310, 320 antenna

330 Framer / Reframer

340 FA type information detector 350 digital channel filter

360 first frequency converter 370 CFR

380 Digital Predistorter 390 DAC

400, 410, 420 ADC

Claims (4)

A main hub unit for wireless communication with the base station; A remote optical unit of a digital optical relay device, comprising a remote optical unit connected to the main hub unit through an optical cable and performing wireless communication with a subscriber station. An optical module for converting a digital optical signal received from the main hub unit into a digital electrical signal, converting a digital electrical signal input from a framer / reframer below into a digital optical signal and transmitting the digital optical signal to the main hub unit; Framer / Reframer; An FA type information detector for detecting the type information of the FA of the digital signal through power detection of the FA of the digital signal input from the framer / reframer; A channel filter unit performing channel filtering using a digital channel filter corresponding to the type information of the FA detected by the FA type information detector; A first frequency converter converting the channel filtered signal into a frequency center so as to position the signal at a center of a bandwidth of a digital pre-distortion unit; A CFR (Crest Factor Reduction) unit for performing CFR processing on the signal output from the first frequency converter; And A digital predistorter configured to receive the output signal of the CFR unit and perform digital predistortion processing; A frequency up-conversion or frequency for the signal output from the digital predistorter in a direction opposite to the frequency converted by the first frequency converter to frequency-convert the signal to the center portion of the bandwidth of the digital predistorter. A second frequency converter configured to down-convert, With power amplifier, A remote optical unit of a digital optical relay system comprising a filter module in which a duplex, a band pass filter (BPF) and an arrester are integrated. The method of claim 1, The FA consists of FA 1, FA 2, FA 3 and FA 4, The type information of the FA is 16 cases determined according to the presence or absence of the FA 1, the FA 2, the FA 3 and the FA 4 remote optical unit of the digital optical relay system. The method of claim 2, The CFR unit, the remote optical unit of the digital optical relay system, characterized in that for applying the CFR factor corresponding to the type information of the FA detected by the FA type information detection unit. The method of claim 2, The channel filter unit may perform channel filtering to improve Adjacent Channel Leakage Ratio (ACLR) using a digital channel filter corresponding to the type information of the FA detected by the FA type information detector. A remote optical unit of a digital optical relay system.

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