KR100299092B1 - Apparatus for processing as to radio frequency of base station - Google Patents

Abstract

The present invention relates to a high frequency processing apparatus of a base station which integrates a high frequency front-end unit into one high frequency processing module to reduce component size and perform RF gain control in the integrated high frequency processing module to improve the performance of the base station apparatus. As the present invention, a variable attenuator for variably attenuating the transmission signal, a power amplifier for power amplifying the high frequency output from the variable attenuator, the output signal of the power amplifier is routed to the antenna side, the signal received at the antenna side Duplexer that sets the path to the receiving side, Coupler that connects the transmission signal through the duplexer to the antenna side and simultaneously returns a signal corresponding to the level of the transmission frequency, Transmission level detector for detecting the power of the transmission signal fed back from the coupler, Transmission level Transmission detected at the detector Transmitting a war toward the main base station, and implemented in accordance with the control signal transmitted from the main base station the first modem for controlling the variable attenuator and a power amplifier having a module structure.

Description

Apparatus for processing as to radio frequency of base station

The present invention relates to a high frequency (RF) front-end (RF) of a micro base station in a mobile communication system (e.g., a CDMA mobile communication system, a personal mobile communication system (PCS), a broadband wireless subscriber network system (WLL system)). Front-End Module. In particular, the high-frequency front-end unit is integrated into a single high-frequency processing module to reduce component size and perform RF gain control in the integrated high-frequency processing module to improve the performance of the base station apparatus. It relates to a high frequency processing apparatus of a base station.

In a typical mobile communication system, there is an RF front-end block for receiving and transmitting a high frequency between a main base station system and a base station antenna, and each module in the RF front-end block is implemented separately from each other.

1 is a schematic configuration diagram of a conventional base station apparatus.

As shown, a transmission digital unit 1 for processing a digital signal to be transmitted to a terminal (mobile station), and an up converter 2 for frequency upconverting the transmission digital signal output from the transmission digital unit 1 to high frequency. And a high power amplifier 3 for high power amplifying the high frequency output from the up-converter 2, and a transmission band filter for filtering the output signal of the high power amplifier 3 to a predetermined band and transmitting it to the transmission antenna 5 side ( 4) and a first antenna and a second antenna for receiving a signal transmitted from a terminal (mobile station) for filtering the signals received at the reception antennas (6) and (7), respectively. First and second low noise amplifiers 10 for amplifying the signals output from the second reception band filter 8 and 9 and the first and second reception band filter 8 and 9, respectively, with a minimum of noise. 11, and the first and second low noise A distribution module 12 for distributing the output signals of the aeration 10 and 11, and first and second down converters 13 for down-converting the received signal distributed by the distribution module 12 to an intermediate frequency ( 14) and first and second receiving digital units 15 and 16 for processing the signals obtained by the first and second down converters 13 and 14, respectively, and processing the signals.

In the conventional base station apparatus configured as described above, when a signal is first transmitted from a base station to a terminal (mobile station), the transmission signal is processed by the transmitting digital unit 1 and then up-converted into the high frequency by the up converter 2. Here, the up converter 2 also performs gain control of the high frequency block (high power amplifier, transmission band filter) for adjusting the cell radius of the base station. In addition, the frequency up-converted transmission signal is power amplified by the high power amplifier 3, filtered by the transmission band filter 4 to a predetermined band, and then transmitted to the terminal through the transmission antenna 5.

Next, when a signal is transmitted from the terminal to the base station, the signal transmitted from the terminal is received at two receiving antennas 6 and 7 for diversity, respectively, having a path difference, and the first and second reception. The band filter 8, 9 filters the signal received from the corresponding antenna into the set band. The filtered received signal is amplified in the first and second low noise amplifiers 10 and 11 in a state where the noise level is minimized, respectively, and then, through the distribution module 12, the first and second down converters 13 ( 14) is delivered. The first and second down converters 13 and 14 frequency down-convert the received received signal to an intermediate frequency, and the received down-converted received signal is converted into a first and second receiving digital unit 15 ( 16) is processed and delivered to the subscriber.

However, in the conventional base station apparatus operated as described above, each module processing high frequency (RF), that is, a high power amplifier, a transmission band filter, a first and a second reception band filter, a first and a second low noise amplifier, and the like Since it is implemented separately for each module, there was a disadvantage that occupies a large size of the device.

In addition, since the up-converter performs a function of controlling the gain of the high frequency block in addition to the frequency up-conversion function, the up-converter has a disadvantage in that the performance is increased due to the load.

Accordingly, the present invention has been proposed to solve various problems occurring in the conventional base station apparatus.

An object of the present invention is to integrate a high frequency front-end unit into one high frequency processing module to reduce component size and to perform RF gain control in the integrated high frequency processing module to improve the performance of the base station apparatus. To provide a device.

The present invention for achieving the above object,

A variable attenuator for variably attenuating the high frequency up-converted by the up converter;

A power amplifier for power amplifying the high frequency output from the variable attenuator;

A duplexer configured to route an output signal of the power amplifier to an antenna side, and to set a path of a signal received at the antenna side to a receiver side;

A coupler for connecting the transmission signal through the duplexer to the antenna side and simultaneously feeding back a signal corresponding to the level of the transmission frequency;

A transmission level detector for detecting the power of the transmission signal fed back from the coupler;

A first modem for transmitting the transmission power detected by the transmission level detector to a main base station and controlling the variable attenuator and the power amplifier according to a control signal transmitted from the main base station;

A first diplexer that mixes and outputs an output signal of a low noise amplifier for low noise amplifying the received signal through the duplexer and a signal output from the first modem, and separates a frequency transmitted from the main base station into a received signal and a control signal Wow;

A second diplexer which separates a signal output from the first diplexer into a received signal and a detection signal, and transmits a control signal output from the main modem to the first diplexer;

The detection signal obtained from the second diplexer is transmitted to the base station manager, and the control signal obtained from the base station manager is configured as a second modem to be transmitted to the second diplexer.

1 is a configuration diagram of a base station apparatus applied to a conventional mobile communication system;

2 is a block diagram of a high frequency processing apparatus of a base station in a mobile communication system according to the present invention.

<Explanation of symbols for main parts of the drawings>

102 variable attenuator 103 high power amplifier

104: duplexer 105: coupler

106: transmission level detector 107: first modem

108: low noise amplifier 109: first diplexer

110: second diplexer 111: second modem

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention according to the technical spirit as described above in detail.

2 is a block diagram of a high frequency processing apparatus of a base station according to the present invention.

Here, reference numeral 101 is an up-converter for up-converting the transmission signal to high frequency, 102 is a variable attenuator for variably attenuating the high-frequency up-converted by the up-converter 101, and 103 is the variable attenuator 103. A power amplifier for power amplifying the high frequency output from the, 104 is the output signal of the power amplifier 103 is a path to the antenna side, the signal received from the antenna side is a duplexer 104 to set the path to the receiving side 105 denotes a coupler for connecting the transmission signal through the duplexer 104 to the antenna side and simultaneously feedback a signal corresponding to the level of the transmission frequency, and 106 indicates a power of the transmission signal fed back from the coupler 105. Transmission level detector.

Further, reference numeral 107 denotes a first unit for transmitting the transmission power detected by the transmission level detector 106 to the main base station and controlling the variable attenuator 102 and the power amplifier 103 according to a control signal transmitted from the main base station. 1 is a modem, 108 is a low noise amplifier for low noise amplification of the received signal through the duplexer 104, 109 is a mixture of the output signal of the low noise amplifier 108 and the signal output from the first modem (107) The frequency transmitted from the main base station is a first diplexer that separates the received signal and the control signal.

In addition, reference numeral 110 denotes a signal which separates the signal output from the first diplexer 109 into a received signal and a detection signal, and transmits a control signal output from the main modem to the first diplexer 109. 2 is a diplexer, and 111 is a second signal that transmits a detection signal obtained from the second diplexer 110 to a base station manager, and a control signal obtained from the base station manager to the second diplexer 110. Modem, 112 is a power divider for power distribution of the received signal obtained from the second diplexer 110, 113, 114 is a first frequency down-converted to the intermediate frequency, respectively, the received signal distributed in the power divider 112 And a second down converter.

The variable attenuator 102, the high power amplifier 103, the duplexer 104, the coupler 105, the transmission level detector 106, the first modem 107, the low noise amplifier 108, and the first diplexer. 109 is actually implemented on one board and collectively referred to as a high frequency front-end block.

The high frequency processing apparatus of the base station according to the present invention configured as described above is largely operated by a high frequency transmission process, a control (variable attenuator and a high power amplifier) and an alarm signal processing process, a high power amplifier alarm alarm process, and a transmission level detection process. Each process will be described separately.

First, referring to the high frequency transmission process, the transmission signal is up-converted to the high frequency in the up converter 101, attenuated according to the attenuation level set in the variable attenuator 102, and then amplified by the high power amplifier 103. The power amplified transmission signal is connected to the transmission path through the duplexer 104, and is connected to the transmission antenna through the coupler 105 which is a directional coupler.

Next, referring to the transmission level detection process, when the transmission level detection command is issued by the base station manager BSM, the second modem 111 converts the signal into an analog signal and transmits the analog signal to the second diplexer 110. The second diplexer 110 transmits the transmitted control command to the first diplexer 109, and the first diplexer 109 transmits the control command to the first modem 107. At this time, the transmission level detector 106 detects the transmission level obtained from the coupler 105 and transmits it to the first modem 107, and the first modem 107 converts it into an analog signal and converts it into an analog signal. 109). The first diplexer 109 combines the transmission level detection signal and the reception signal and transfers them to the second diplexer 110. The second diplexer 110 receives the reception signal and the transmission level detection signal. The distribution signal is transmitted to the power divider 112 and the transmission level detection signal is transmitted to the second modem 111. The second modem 111 converts it into a digital signal and transmits it to the base station manager BSM, which is an upper block.

Next, the control (variable attenuator and high power amplifier) and the alarm signal processing process are as follows.

First, the control of the variable attenuator 102 analyzes the transmission level in the base station manager BSM and transfers the control value to the second modem 111 as described above. The second modem 111 converts it into an analog signal and transmits the converted analog signal to the second diplexer 110. The second diplexer 110 transmits the transmitted control command signal to the first diplexer 109, and the first diplexer 109 transmits it to the first modem 107. The first modem 107 controls the variable attenuator 102 by setting the attenuation value of the variable attenuator 102 according to the transmitted control command value.

In addition, the control of the high power amplifier 103 is also made of the same process as the control process of the variable attenuator 102 described above, except that the control of the high power amplifier 103 is not controlled according to a level value, but is on / off. Control is done.

Next, referring to the alarm alarm process of the high power amplifier, the alarm signal generated by the high power amplifier 103 is converted into an analog signal in the first modem 107 and transmitted to the first diplexer 109. The first diplexer 109 combines the alarm signal and the received signal transmitted from the low noise amplifier 108 and transmits the combined signal to the second diplexer 110. The second diplexer 110 separates an input signal into a received signal and an alarm signal, transfers the separated received signal to the power divider 112, and transfers the separated alarm signal to the second modem 111. do. The second modem 111 converts the transmitted analog alarm signal into a digital signal and delivers it to the base station manager BSM to process the alarm alarm.

In addition, when an alarm occurs in another block, for example, the low noise amplifier 108, the alarm is processed through the same path as the alarm processing of the high power amplifier 103 described above.

As described above, the present invention has the advantage of reducing the component size of the device by implementing each module in the high frequency processing block in one module (board).

In addition, when the high frequency processing block is installed outdoors in a tower top base station, transmission power control can be performed by an outdoor modem (first modem), thereby enabling efficient operation of the device.

In addition, since the control signal and alarm signal are transmitted through the modem and the existing reception line, the cable required for the alarm processing or the control signal transmission can be removed as in the past, so the device is easy to configure and the system management is easy. There is a convenient advantage.

Claims (3)

In the base station apparatus, A variable attenuator for variably attenuating the output signal of the up-converter for up-converting the transmission signal to a high frequency; A power amplifier for power amplifying the high frequency output from the variable attenuator; A duplexer configured to route an output signal of the power amplifier to an antenna side, and to set a path of a signal received at the antenna side to a receiver side; A coupler for connecting the transmission signal through the duplexer to the antenna side and simultaneously feeding back a signal corresponding to the level of the transmission frequency; A transmission level detector for detecting the power of the transmission signal fed back from the coupler; A first modem for transmitting the transmission power detected by the transmission level detector to a main base station and controlling the variable attenuator and the power amplifier according to a control signal transmitted from the main base station; A first diplexer which combines an output signal of a low noise amplifier for low noise amplifying the received signal through the duplexer and a signal output from the first modem, and separates a frequency transmitted from the main base station into a received signal and a control signal High frequency processing apparatus of the base station, characterized in that configured to include. 2. The apparatus of claim 1, further comprising: a second diplexer which separates a signal output from the first diplexer into a received signal and a detection signal, and transmits a control signal output from the main modem to the first diplexer; The detection signal obtained from the second diplexer is transmitted to the base station manager, and the control signal obtained from the base station manager further includes a second modem configured to transmit the second diplexer. Device. The apparatus of claim 1, wherein the variable attenuator, the high power amplifier, the duplexer, the coupler, the transmission level detector, the first modem, the low noise amplifier, and the first diplexer are implemented in one module.