KR20110115280A - Remote radio head including front end unit integrated rf power monitoring module and method for mornitoring rf power thereof - Google Patents

Abstract

The present invention relates to a remote radio head and an RF power monitoring method including a transmission and reception front end integrated with an RF power monitoring module capable of reducing the size of a remote wireless base station device and improving skirt characteristics of the transmission and reception front end. As described above, the present invention provides a power supply unit for supplying power to a remote radio head (RRH), and a high power linear amplification unit for amplifying and supplying a high power radio frequency (RF) power to a transmission and reception front end portion and transmitting a signal between the base station and the RRH system unit. A remote radio head system unit comprising a signal processing unit for coding / decoding and baseband signal processing, and an optical module unit for performing optical communication with the base station, and when the transmission signal is input from the RRH system unit, filtering is performed to limit the band to a signal in a passband. A transmission filter unit transmitting through an antenna, a first reception filter unit for performing band-limiting filtering to a signal in a passband when a signal is received through the antenna, and low noise for low noise amplification of the received signal filtered by the first reception filter unit A second amplifier performing filtering to improve a skirt characteristic of the low noise amplified received signal; A remote radio head transmitting and receiving front end unit including an RF power monitoring unit for monitoring forward power information, reverse power information, and standing wave ratio information of the reception filter unit, the transmission filter unit, and the first reception filter unit; Provided is a remote radio head including a transmission and reception front end integrated with a power monitoring module.

Description

Remote radio head including a front end unit and a front end unit integrating a radio frequency power monitoring module and a method for monitoring the radio frequency power thereof.

The present invention relates to a remote radio head including a transmission and reception front end integrated with a radio frequency (RF) power monitoring module. Particularly, a front end of a transmission and reception power transmission module included in a remote radio head (RRH) is used. Transmitter and receiver integrated with RF power monitoring module integrated in unit (FEU) and adopting dual band pass filter of transmission and reception front end to reduce the size of remote wireless base station device and improve skirt characteristics of transmission and reception front end. The present invention relates to a remote radio head including a front end and a method for monitoring RF power thereof.

The mobile base station amplifies a signal to be transmitted by a high power amplifier located in the base station when transmitting a signal, and then transmits a transmission signal to an antenna installed in a tower through a feed cable, and the antenna installed in the tower radiates a transmission signal. In addition, in the mobile communication base station system, the antenna installed in the tower receives the signal and transmits the signal to a low noise amplifier in the base station through a feed cable to amplify the weak received signal.

The transmission output of the base station means a serviceable range, that is, coverage, and in particular, means cell coverage in which the base station can provide a service. In general, the forward coverage of the mobile communication is mainly based on the reception level of the terminal, and the mobile communication service providers are making great efforts to improve this.

According to the configuration and operation of the mobile communication service, a base station including a high power linear amplification unit is installed on the ground, and transmits a transmission signal output from the base station to a service tower on a steel tower or telephone pole using a feed line. At this time, the loss caused by the feed line varies slightly depending on the type and length of the cable, but a transmission loss of about 3dB to 5dB occurs.

Hereinafter, a signal transmission and reception structure between a base station and an antenna according to the prior art will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to an example of the related art. In the signal transmission / reception structure between the base station and the antenna according to the prior art, a coaxial cable 3 is formed between the base station 1 and the antenna 2 as shown in FIG. 1. That is, the transmission and reception signals between the base station 1 and the antenna 2 are transmitted and received using a coaxial cable as a feed line for feeding the antenna 2. At this time, the coaxial cable (3) is a kind of transmission line used for wireless communication that can transmit an electrical signal because the outer conductor and the inner conductor are concentric circles. In general, the transmission line is composed of a long cylindrical outer conductor and one inner conductor placed on its central axis. As a cross section of the line, the outer conductor and the inner conductor form concentric circles. In addition, even if a plurality of coaxial cables are accommodated in the same cable, there is an advantage of less signal leakage between each other. However, such a coaxial cable 3 has a problem that a transmission loss of about 5 dB occurs with a loss ratio of the output power of the base station 1 of about 60 to 70%. Therefore, since it is included in the overall noise in the base station receiver as it decreases the reception sensitivity, and the base station transmitter requires a high output to compensate for the loss, a separate high output linear amplifier is required in the base station 1 for high power. This causes a problem that consumes a lot of power.

2 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to another example of the related art. The signal transmission and reception structure between the base station and the antenna according to another example of the prior art is to solve the problem of the signal transmission and reception structure between the base station and the antenna according to an example of the prior art shown in FIG.

In another example of such a prior art, a tower mount amplifier (TMA) 4 is further configured in the coaxial cable 3 between the base station 1 and the antenna 2. Such a TMA (Tower Mount Amplifier) or TTA (Tower Top Amplifier) 4 is used to compensate for transmission losses incurred in the coaxial cable 3 used as a feed line.

The TMA or TTA is a low noise amplifier and a high output linear amplifier of the base station 1, and is installed directly below the service antenna on the tower or the pole of the base station to minimize the transmission loss caused by the feed line coaxial cable (3). Device.

However, TMA (4) or TTA according to another conventional example has a lot of difficulties in operating and maintenance due to the poor installation environment due to the environment in which the base station (1) is installed is affected by the surrounding environment, maintenance Difficult to embed high-power linear amplifiers was difficult and only the bandpass filter and low-noise amplifiers, which are less affected by the environment above, could be configured with TMA or TTA, especially provided by base station (1) in case of failure of devices such as TMA or TTA There is a problem that the mobile communication service is disconnected. In addition, there is still a problem that the loss ratio of the output power at the base station 1 is 50% even when using the TMA 4 or the TTA without such a high output linear amplifier. At this time, even when the TMA 4 is used for the coaxial cable 3 between the base station 1 and the antenna 3, a transmission loss of about 4 dB is generally generated.

3 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to still another example of the prior art. The signal transmission and reception structure between the base station and the antenna according to another example of the prior art includes a base station 1 and an antenna 2. The transmission line between the ()) is composed of an optical cable (5), and a remote radio head (RRH) 6 is formed between the base station 1 and the antenna (2).

Here, the optical cable 5 is a cable that converts an electrical signal into a light signal and transmits it through a glass fiber, also called an optical fiber cable. As such, the optical cable 5 has a wider bandwidth than other wired transmission media, so the data transmission rate is excellent, and the size and weight thereof are small, so that the size of the supporting structure can be reduced and transmitted in the form of light, such as impact noise, crosstalk, etc. There is an advantage that does not receive external interference. In other words, the optical cable 5 has an advantage that there is no loss of output power (No loss).

On the other hand, the RRH (6) is a remote RF transceiver for a base station (NodeB), and connects the base station with an optical cable 5 to a remote site (Remote Site) far from the base station, and converts the digital signals and control signals converted into optical signals (optical cable ( 5) exchange each other through In general, there is an advantage that the installation is easy due to the small size of about 20kg in weight, less than 30 liters in volume. At this time, the base station 1 digitally processes the baseband signal, converts the coded signal into an optical signal, and transmits the converted signal to the RRH 6. Then, the RRH 6 receives the signal transmitted from the base station, processes the digital signal, decodes it, and processes the decoded signal to the baseband signal to upconvert the RF signal.

FIG. 4 is a block diagram illustrating a signal transmission / reception structure between the remote radio head RRR and the antenna shown in FIG. 3 in detail. As shown in FIG. 4, the RRH 6 shown in FIG. 3 is comprised from the RRH system part 10 and the RRH front-end unit 20. As shown in FIG.

The RRH system unit 10 includes a power supply unit 11, a high output linear amplifier unit 12, a signal processing unit 13, an optical module unit 14, and an RF power monitoring unit 15.

Here, the power supply unit 11 supplies power to the RRH system unit 10 and the RRH front-end unit 20. That is, power is supplied to the entire RRH 6 including the RRH system unit 10 and the RRH transmission and reception front end unit 20.

The high output linear amplifier 12 amplifies the high power RF power and supplies the amplified high power RF power to the RRH transceiver front end 20.

Meanwhile, the signal processor 13 digitally processes the baseband signal by processing the baseband signal, decodes the coded signal by digital signal processing, and converts the decoded signal into a baseband signal to upconversion to an RF signal. To the high output linear amplifier 12.

The optical module unit 14 performs optical communication with the base station.

The RF power monitoring unit 15 monitors the RF power (RF POWER) at the time of signal transmission and reception by the measurement unit 24 between the RRH transmission and reception front end 20 and the antenna 30. Here, the RF power monitoring unit 15 is configured in an independent module form inside the RRH system unit 10.

On the other hand, the RRH transmission / reception front end part 20 is comprised from the transmission filter 21, the reception filter 22, and the low noise amplifier (LNA) 23. As shown in FIG.

Here, when the RF signal is input, the transmission filter 21 performs a band limiting filtering to a signal in the pass band. The signal passing through the transmission filter 21 is transmitted through the antenna 30.

When the signal is received through the antenna 30, the reception filter 22 performs band limiting to a signal in the pass band.

The low noise amplifier 23 low noise amplifies the filtered received signal.

Therefore, such a prior art had the following problems.

First, since the RF power monitoring module is configured as a separate module in the remote radio head (RRH), a space for installing the module is required, and accordingly, the overall size of the remote radio head is large and heavy.

Second, since the transmission and reception front end is composed of only one reception filter, there is a limit in reducing the noise figure.

Accordingly, the present invention is to solve all the disadvantages and problems of the prior art as described above, the present invention is a front end unit for transmitting and receiving RF power monitoring module included in a Remote Radio Head (RRH): Transmitting and receiving front end integrated with RF power monitoring module integrated in FEU) and adopting dual band pass filter of transmitting and receiving front end to reduce the size of remote wireless base station device and improve skirt characteristics It is an object of the present invention to provide a remote radio head and a method for monitoring RF power thereof.

In order to achieve the above object, the present invention provides a remote radio head comprising a remote radio head (RRH) system unit, a remote radio head (RRH) transmission and reception front end, a remote radio comprising an RRH system unit and an RRH transmission and reception front end. A power supply unit for supplying power to the head (RRH), a high output linear amplification unit for amplifying and supplying high-frequency RF power to the transmission and reception front end, and coding / decoding and baseband for transmission signals between the base station and the RRH system unit. A remote radio head system unit comprising a signal processing unit for signal processing and an optical module unit for performing optical communication with a base station, and when a transmission signal is input from the RRH system unit, transmission is transmitted through an antenna by performing band-limiting filtering to signals in a pass band. Filter that limits the band to the signal in the pass band when the signal is received through the filter unit and the antenna A first receiving filter unit for ringing, a low noise amplifier for low noise amplifying the received signal filtered by the first receiving filter unit, a second receiving filter unit for filtering to improve skirt characteristics of the low noise amplified received signal, and An RF power monitoring module comprising: a remote radio head transmitting and receiving front end including an RF power monitoring means for monitoring forward power information, reverse power information, and standing wave ratio information of a transmission filter unit and a first reception filter unit; Provided is a remote radio head including an integrated transmission and reception front end.

Here, the RF power monitoring means is preferably composed of a microprocessor for RF power monitoring.

In addition, it is preferable that an analog / digital conversion unit for analog-to-digital conversion of forward power information and reverse power information is further configured between the RF power monitoring means and the antenna.

In addition, the present invention for achieving the above object, the RF power monitoring means for monitoring the radio frequency (RF) power in the front end of the RRH transmission and reception, and the improvement of the skirt characteristics of the signal amplified in the low noise amplifier for low noise amplification of the received signal Installing a second reception filter unit next to the low noise amplifier; Filtering the received signal received through the antenna to a pass band in a first reception filter unit of a transmission and reception front end; Amplifying the passband received signal filtered by the first reception filter in the low noise amplifier; Performing filtering to improve the skirt characteristic of the second reception filter unit on the received signal amplified by the low noise amplifier; Monitoring forward power information, reverse power information, and standing wave ratio information between the remote radio head transmission and reception front end, the antenna, and transmitting the forward power information, the reverse power information, and the standing wave ratio information by the RF power monitoring means to the remote radio head system unit; And adjusting a power source to be used as forward power and reverse power according to the forward power information, the reverse power information, and the standing wave ratio information. A method of monitoring radio frequency power of a remote radio head is provided.

Here, the RF power monitoring means is preferably integrated into a microprocessor for RF power monitoring.

According to the present invention has the following effects.

First, in configuring the filter of the transmission and reception front end, it is possible to minimize the insertion loss by implementing in a dual manner. In other words, the noise figure and skirt characteristics of the received signal can be improved.

Second, the overall size of the remote radio head can be reduced by integrating the power monitoring module configured as a separate module in the remote radio head RRR. Therefore, it is possible to reduce the weight of the remote radio head by reducing the overall size of the remote radio head.

1 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to an example of the prior art;
2 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to another example of the prior art;
3 is a block diagram illustrating a signal transmission and reception structure between a base station and an antenna according to another example of the prior art;
4 is a block diagram illustrating in detail the signal transmission and reception structure between the remote radio head (RRH) and the antenna shown in FIG.
5 is a view for explaining a remote radio head having a transmitting and receiving front end integrated RF power monitoring module according to the present invention;
6 and 7 are a view for explaining the insertion loss (reception loss) of the reception filter of the transmission and reception front end in the remote radio head having a transmission and reception front end incorporating the RF power monitoring module according to the prior art and the present invention;
8 is a flowchart illustrating an RF power monitoring method of a remote radio head having a transmission / reception front end integrated with an RF power monitoring module according to the present invention.

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

In addition, although the term used in the present invention is selected as a general term that is widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, since the meaning is described in detail in the description of the relevant invention, It is to be understood that the present invention should be grasped as a meaning of a term that is not a name of the present invention. Further, in describing the embodiments, descriptions of technical contents which are well known in the technical field to which the present invention belongs and which are not directly related to the present invention will be omitted. This is for the sake of clarity of the present invention without omitting the unnecessary explanation.

5 is a view for explaining a remote radio head having a transmitting and receiving front end integrated RF power monitoring module according to the present invention. As shown in FIG. 5, the remote radio head (RRH) having an RF transceiver module integrated with the RF power monitoring module according to the present invention is connected to an RRH system unit 100 and an RRH transceiver end unit 200. It is composed.

Here, the RRH system unit 100 includes a power supply unit 110, a high output linear amplifier 120, a signal processor 130, and an optical module unit 140.

Here, the power supply unit 110 supplies power to the RRH system unit 100 and the RRH transmission and reception front end 200. That is, power is supplied to the entire RRH including the RRH system unit 100 and the RRH transmission / reception front end unit 200.

The high output linear amplifier 120 amplifies the high power RF power and supplies the amplified high power RF power to the RRH transceiver front end 200.

Meanwhile, the signal processor 130 digitally processes the baseband signal at the base station to digitally process and decode the coded signal, and processes the decoded signal to baseband signal to upconvert the RF signal to upconvert to an RF signal. Transmission to the amplifier 120. In addition, the signal processor 130 down-converts the signal received through the antenna 300 and filtered and low-noise amplified by the RRH transceiver front-end 200 to process the baseband signal, and to code and digitally process the signal. Convert to an optical signal. The signal processor 130 may configure a DSP chip.

The optical module unit 140 performs optical communication between the base station and the RRH system unit 100.

On the other hand, the RRH transmission and reception front end 200, the transmission filter unit 210, the first receiving filter unit 220, low noise amplifier (LNA) 230, the second receiving filter unit 250 and RF power monitoring means 260.

In this case, when the transmission signal is input from the RRH system unit 100, the transmission filter unit 210 performs band limiting to a signal in a pass band. The signal passing through the transmission filter 210 is transmitted through the antenna 300.

When the signal is received through the antenna 300, the first reception filter unit 220 performs band limiting to a signal in a pass band.

The low noise amplifier 230 low noise amplifies the filtered received signal.

The second reception filter unit 250 filters to improve a skirt characteristic of the low noise amplified received signal.

The RF power monitoring unit 260 monitors RF power at the time of transmitting and receiving a signal in the measuring unit 240 between the RRH transmission and reception front end 200 and the antenna 300. At this time, the RF power monitoring means 260 transmits forward power information, reverse power information, and standing standing wave ratio (VSWR) information to the RRH system unit 100. Here, the RF power monitoring means 260 may be configured as a microprocessor for RF power monitoring. On the other hand, between the RF power monitoring means 260 and the measurement unit 240 is further configured A / D conversion unit 270, 280 for analog-to-digital conversion of power information at the time of signal transmission and reception.

In the present invention as described above, the RRH system unit 100 is miniaturized by configuring the RF power monitoring unit, which is conventionally configured in a separate module form inside the RRH system unit 10, as a microprocessor in the RRH transmission / reception front end unit 200. It can be seen that the weight can be reduced.

6 and 7 illustrate insertion loss of a reception filter of a transmission and reception front end in a remote radio head having a transmission and reception front end incorporating an RF power monitoring module according to the related art. 6 and 7, the filter structure of the RRH transmission / reception front end part 200 according to the present invention includes a first reception filter part 220 and a second reception filter part at the front and rear ends of the low noise amplifier 230. 250, the insertion loss is reduced as in "b" of FIG. 7 compared to "a" of FIG. 5, and the skirt characteristics are also improved as in "d" of FIG. Able to know. That is, when the noise figure of FIG. 5 is referred to as NF1 and the noise figure in FIG. 7 is referred to as NF2, it can be seen that the noise index of NF2 is further reduced.

8 is a flowchart illustrating an RF power monitoring method of a remote radio head having a transmitting and receiving front end unit integrating an RF power monitoring module according to the present invention. RF power monitoring method of the remote radio head having a transmission and reception front end integrated RF power monitoring module according to the present invention, as shown in Figure 8, first, RF power monitoring means for RF power monitoring on the RRH transmission and reception front end 200 In operation S100, a second reception filter unit 250 is further installed to improve skirt characteristics of the signal amplified by the low noise amplifier 230. Here, when the RF power monitoring means 260 is configured as an RF power monitoring microprocessor rather than a separate module type, the RF power monitoring means 260 may be integrated and formed in the RRH transmission / reception front end 200.

Subsequently, the reception signal received through the antenna 300 is filtered by the first reception filter 220 of the RRH transmission / reception front end 200 into the pass band (S120).

Next, the passband received signal filtered by the first reception filter 220 is amplified by the low noise amplifier 230 (S140).

In operation S160, the second reception filter unit 250 performs filtering to improve the skirt characteristic on the received signal amplified by the low noise amplifier 230. That is, by implementing the reception filter in a dual manner, insertion loss can be minimized, and the skirt characteristic of the reception signal can be improved.

On the other hand, the RF power monitoring means 260 determines whether the period for monitoring the forward power information, the reverse power information and standing wave ratio information has reached (S180).

If the determination result (S180) has been set cycle, the forward power information, the reverse power information and the standing wave ratio information is monitored and transmitted to the RRH system unit 100 side, accordingly to adjust the RF power used as the forward power, reverse power, RRH The abnormal state is monitored (S200).

Although the present invention has been described by way of example as described above, the present invention is not necessarily limited to these examples, and various modifications can be made without departing from the spirit of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the technical idea of the present invention but to explain the present invention, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: remote radio head 110: power supply
120: high output linear amplifier 130: signal processor
140: optical module portion 200: transmission and reception front end
210: transmission filter unit 220: first reception filter unit
230: low noise amplifier 240: measurement unit
250: second receiving filter unit 260: RF power monitoring means
270, 280: converter 300: antenna

Claims (5)

In the remote radio head composed of a remote radio head (RRH) system unit 100 and a remote radio head (RRH) transmission and reception front end 200,
A high frequency radio frequency output to the RRH system unit 100, the power supply unit 110 for supplying power to the remote radio head (RRH) consisting of the RRH transmission and reception front end 200, and the transmission and reception front end 200 A high output linear amplification unit 120 for amplifying and supplying (RF) power, a signal processing unit 130 for processing coding / decoding, and baseband signals between a base station and the RRH system unit 100, and the base station; Remote radio head system unit 100 is composed of an optical module 140 for performing optical communication, and
When the transmission signal is input from the remote radio head system unit 100, the transmission filter unit 210 transmits through the antenna 300 by performing the band-limiting filtering to the signal in the pass band, and the signal through the antenna 300. Receiving the first reception filter 220 for performing band-limiting filtering to a signal in the passband, the low noise amplification unit 230 for low noise amplifying the received signal filtered by the first reception filter 220, Forward power information and reverse power information of the second reception filter unit 250 and the transmission filter unit 210 and the first reception filter unit 220 for filtering to improve a skirt characteristic of the low noise amplified reception signal; A remote radio head transceiver front and rear part 200 including an RF power monitoring means 260 for monitoring the standing wave ratio information; Remote radio head box. The method of claim 1,
The RF power monitoring means 260 is a remote radio head including a transmitting and receiving front end integrated RF power monitoring module, characterized in that consisting of a microprocessor for RF power monitoring.
The method of claim 1,
Between the RF power monitoring means 260 and the antenna 300, an analog / digital conversion unit 270, 280 for analog / digital conversion of forward power information and reverse power information is further configured RF Remote radio head including a transmission and reception front end integrated power monitoring module.
A radio frequency power monitoring method of a remote radio head (RRH) comprising a remote radio head (RRH) transmitting and receiving front end portion incorporating a radio frequency (RF) power monitoring module according to claim 1,
RF power monitoring means 260 for the radio frequency (RF) power monitoring to the RRH transmission and reception front end 200, and to improve the skirt characteristics of the signal amplified by a low noise amplifier 230 for low noise amplifying a received signal Installing a second receiving filter unit 250 at a stage next to the low noise amplifying unit 230 (S100);
Filtering the received signal received through the antenna (300) by the first reception filter unit (220) of the transmission and reception front end unit (200) (S120);
Amplifying the passband received signal filtered by the first reception filter 220 in the low noise amplifier 230 (S140);
Performing filtering to improve the skirt characteristic of the second reception filter unit 250 on the received signal amplified by the low noise amplifier 230 (S160);
The RF power monitoring means 260 monitors forward power information, reverse power information, and standing wave ratio information between the remote radio head transceiver front end 200 and the antenna 300 to monitor the forward power information and the reverse power information. Transmitting the standing wave ratio information to the remote radio head system unit (100) (S180); And,
Transmitting and receiving the integrated radio frequency power monitoring module comprising a; step (S200) of adjusting the power used as the forward power, reverse power in accordance with the forward power information, reverse power information and standing wave ratio information. Radio frequency power monitoring method of a remote radio head comprising a part. The method of claim 4, wherein
The RF power monitoring means (260) is a radio frequency power monitoring method of a remote radio head comprising a transmission and reception front end integrated radio frequency power monitoring module, characterized in that the integrated microprocessor for RF power monitoring.

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