KR100295829B1 - Apparatus for supply signal and power in base station using tower-top form - Google Patents

Abstract

The present invention implements a signal and power supply for supplying the signal and power to the tower-tower installed outdoors and a spare amplifier for compensating for the loss of the connection cable between the outdoor device and the indoor device as a single device installed in the indoor device Accordingly, the present invention relates to a signal and power supply of a tower-top base station, which simplifies the overall system configuration and facilitates maintenance and repair. The present invention provides a transmission signal and a DC voltage provided in an indoor device and output from a transceiver. And a line loss compensator for compensating the line loss of the transmission signal in advance and transmitting it to the line, it is possible to compensate for the loss of the line and facilitate the implementation of the system. In addition, by implementing the line loss compensation unit in redundancy, stabilization can be achieved.

Description

Apparatus for supply signal and power in base station using tower-top form}

The present invention relates to a code division multiple access (CDMA) base station, and more particularly, to a base station apparatus using a tower-top antenna, a signal for supplying signals and power to a tower-top installed outdoors; The tower-top system simplifies the overall system configuration and facilitates maintenance and repair by implementing a single amplifier installed in the indoor unit to compensate for the loss of the connection cable between the power supply unit and the outdoor unit and the indoor unit. A signal and a power supply of a base station.

In general, the tower-top method includes a transmitter-side amplifier and a receiver-side low noise amplifier in an existing antenna radiation module, and installs it at the end of the antenna tower. It is economical because it can be used as a small power amplifier, and there is an advantage of not using expensive cables to antenna radiation module.

In addition, since the low-noise amplifier is located at the antenna end during reception, the call quality can be improved by improving the energy-to-noise ratio (E _b / N _o ). Recently, the tower-top method is mainly applied to base station devices because of various advantages and possible miniaturization of the system.

1 is a schematic block diagram of a conventional tower-top base station apparatus.

As shown, the base station apparatus is roughly divided into the indoor apparatus 10 and the outdoor apparatus 20, and the indoor apparatus 10 controls the base station for interfacing the received voice PCM signal and the received PCM voice signal obtained from the base station controller. And encoding, interleaving, and QPSK-modulating the transmission PCM signal obtained by the base station control and interface unit 11 into an intermediate frequency of a predetermined band, and QPSK demodulation, deinterleaving, decoding from the received frequency. The modulation and demodulation unit 12 for restoring the original signal, and up-converts the transmission intermediate frequency signal obtained from the modulation and demodulation unit 12 to the reception frequency band of the subscriber station, and the received frequency is converted into the intermediate frequency. A preliminary increase to prevent line loss by amplifying the downlink transceiver 13 and the transmission frequency obtained by the transceiver 13 in advance; It consists of a group 14, a signal and a power supply (15) for coupling to output a direct-current voltage input from the output signal and the outside of the pre-amplifier 14.

In addition, the outdoor device 20 receives the main amplifier 21 for power amplification by receiving the signal and the transmission signal output from the power supply unit 15 through the line, and the transmission signal amplified by the main amplifier 21 The signal radiated on the space and transmitted from the subscriber is composed of a copy module 22 for receiving and a low noise amplifier 23 for low noise amplifying the signal received by the copy module 22.

The conventional tower-top base station apparatus configured as described above is operated by a forward link and a reverse link, and hereinafter, it will be described separately for better understanding.

First, in the forward link, the base station control and interface unit 11 in the indoor device 10 interfaces with the voice PCM signal received from the base station controller and transmits it to the modulation and demodulation unit 12.

The modulator and demodulator 12 encodes, interleaves, and QPSK modulates the transmitted voice PCM signal, and inputs it to the transceiver 13 as an intermediate frequency signal of 4.95 MHz.

The transceiver 13 converts an input frequency signal of 4.95Mhz into a digital cellular band (DCS: 800Mhz) or a personal mobile communication system band (PCS: 1.8Ghz) and outputs the frequency.

The output transmission channel signal is input to the preamplifier 14, and the preamplifier 14 has a capacity of 2W to 5W, and amplifies the input transmission channel signal to a predetermined level to compensate for line loss. The amplified signal is combined with a DC voltage (DC voltage) input from the outside to output the signal and the power supply line to the transmission line.

Here, the conventional circuit of the signal and power supply unit 15 as described above is shown in FIG.

As shown in the drawing, the input transmission channel signal is output to the output through the condenser C, and the DC voltage input from the outside is input through the inductor L to be added to the transmission channel signal and output. Since the input channel signal is a high frequency signal, it is open in the inductor (L) and does not flow to the inductor (L), but instead goes out to the output. In addition, the input DC voltage does not flow to the capacitor (C) and is output directly. Will exit.

On the other hand, as described above, the signal in the indoor device 10 and the transmission channel signal output from the power supply unit 15 is transmitted to the outdoor device 20 through the transmission line 31, at this time the signal due to the transmission line 31 Although not shown in the drawing to prevent loss, a line amplifier as shown in FIG. 3 is positioned at a predetermined position of an outdoor line to amplify a signal.

That is, a transmission signal and a DC voltage are applied to the input terminal of the line amplifier, and the input transmission signal is directly inputted to the amplifier Amp without being passed through the inductors L1 and L2, and amplified to a predetermined level, and then passed through the capacitor C2. To the output stage. In addition, the input DC voltage is directly outputted through the inductors L1 and L2 without affecting the input terminal or the output terminal of the amplifier A by the capacitor C1 and the capacitor C2.

The signal transmitted via the transmission line 31 is then power amplified by the main amplifier 21 in the outdoor device 20 and radiated into the air at the desired beam width by the radiation module 22.

Meanwhile, the signal transmitted by the subscriber is received by the copy module 22 and converted into a CDMA reverse channel signal, and the signal is amplified to a predetermined level in a state in which the noise is minimized in the low noise amplifier 23, so that the receiving line 32 is closed. It is delivered to the indoor device 10 through. Here, the operation of the low noise amplifier 23 improves the energy-to-noise ratio of the received signal.

In addition, the signal input to the indoor device 10 through the receiving line 32 is frequency down-converted into a 4.95Mhz intermediate frequency signal by the transceiver 13, and the demodulation and demodulation unit 12 is demodulated.

The demodulated voice PCM signal is transmitted to the well-known base station controller by the interface of the base station control and interface unit 11.

However, the conventional tower-top base station apparatus uses a signal and a power supply to supply power to an amplifier installed in the tower-top, and the signal and power supply simply provide a signal and power. In order to prevent extra signal loss, a spare amplifier is provided. As a result, there is a problem that the implementation of the base station indoor device is complicated.

In addition, indoor devices and outdoor devices are connected by a line, and a line amplifier is added in the middle of the line to prevent the loss of the line. In this case, the line amplifier is installed outdoors, which is difficult to maintain and repair. The problem of temperature also has to be solved.

Therefore, the present invention has been proposed to solve various problems occurring in the conventional tower-top base station apparatus as described above,

An object of the present invention is to implement a signal and power supply for supplying a signal and power to the tower tower installed outdoors, and a spare amplifier to compensate for the loss of the connection cable between the outdoor device and the indoor device as a single device indoors By installing in the device, it is to provide a signal and power supply of the tower-top base station to simplify the overall system configuration and to be easy to maintain and repair.

Embodiment of the signal and the power supply according to the present invention for achieving the above object,

Base station control and interface section, modulation and demodulation section. A tower-top base station apparatus comprising an indoor device composed of a transceiver and an outdoor device formed of a main amplifier, a radiation module, and a low noise amplifier connected to the indoor device through a line.

It is provided in the indoor device, characterized in that it comprises a line loss compensation means for combining the transmission signal and the DC voltage output from the transceiver, and compensates the line loss of the transmission signal in advance to the line.

The line loss compensation means in the above,

A variable attenuator for attenuating the input transmission signal by a line loss compensation value; An amplifier for amplifying the transmission signal attenuated by the variable attenuator to a predetermined level; An inductor receiving a DC voltage for transmission to an antenna module and preventing a transmission signal output from the amplifier from being transmitted to the DC voltage input side; And a capacitor interposed between the inductor and the amplifier to prevent a DC voltage input through the inductor from being transferred to an output terminal of the amplifier.

Another embodiment of the signal and power supply according to the present invention for achieving the above object,

Base station control and interface section, modulation and demodulation section. A tower-top base station apparatus comprising an indoor device composed of a transceiver and an outdoor device formed of a main amplifier, a radiation module, and a low noise amplifier connected to the indoor device through a line.

A first line loss compensator provided in the indoor device, combining a transmission signal and a DC voltage output from the transceiver and compensating for the line loss of the transmission signal in advance;

A first power supply unit supplying driving power into the first line loss compensation unit;

A comparison unit for comparing the power supplied from the first power supply unit with a reference voltage and generating a selection signal for selecting a transmission signal as a result value;

A second line loss compensator provided in the indoor device, combining a transmission signal and a DC voltage output from the transceiver, and compensating for the line loss of the transmission signal in advance;

A second power supply unit supplying driving power into the second line loss compensation unit;

And a transmission signal selector for selecting and outputting one of the transmission signals respectively output from the first and second line loss compensators according to the selection signal output from the comparator.

In the above, the first and second line loss compensation unit,

A variable attenuator for attenuating the input transmission signal by a line loss compensation value; An amplifier for amplifying the transmission signal attenuated by the variable attenuator to a predetermined level; An inductor receiving a DC voltage for transmission to an antenna module and preventing a transmission signal output from the amplifier from being transmitted to the DC voltage input side; And a capacitor interposed between the inductor and the amplifier to prevent a DC voltage input through the inductor from being transferred to an output terminal of the amplifier.

1 is a system schematic configuration diagram of a conventional tower-top base station;

2 is a schematic diagram of a signal and power supply device applied to FIG. 1;

3 is a configuration diagram of a line amplifier applied to FIG. 1;

4 is a system configuration diagram of a tower-top base station to which a signal and a power supply device according to the present invention are applied;

5 is a signal and power supply circuit diagram according to the present invention;

FIG. 6 is a circuit diagram of a redundancy device in which signals and a power supply device according to the present invention of FIG. 5 are duplicated.

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

100: indoor device 140: line loss compensation unit

141: variable attenuator 142: amplifier

310 and 340: first and second line loss compensation unit

320, 350: first and second power supply

330: comparison unit 360: transmission signal selection unit

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

4 is a schematic block diagram of a base station apparatus to which a tower-top system to which a signal and a power supply apparatus are applied according to the present invention.

As shown, the base station apparatus is roughly divided into the indoor apparatus 100 and the outdoor apparatus 200, and the indoor apparatus 100 controls the base station for interfacing the received voice PCM signal and the received PCM voice signal obtained from the base station controller. And encoding, interleaving, and QPSK-modulating the transmission PCM signal obtained by the base station control and interface unit 110 to an intermediate frequency of a predetermined band, and performing QPSK demodulation, deinterleaving, and decoding from the received frequency. The modulation and demodulation unit 120 for restoring the original signal, and up-converts the transmission intermediate frequency signal obtained from the modulation and demodulation unit 120 to the reception frequency band of the subscriber station, and the received frequency is converted into the intermediate frequency. Transceiver 130 for down-converting, combines the transmission signal and the direct current voltage output from the transceiver 130, the line of the transmission signal Compensate for the loss in advance to consist of line loss compensation unit (140) for transmitting to the track.

In addition, the outdoor device 200 receives the main amplifier 210 for power amplification by receiving the transmission signal output from the line loss compensation unit 140 and the transmission signal amplified by the main amplifier 210. The signal transmitted from the subscriber and copied on the space is received by the radiation module 220, and the low noise amplifier 230 for low noise amplification of the signal received by the radiation module 220.

The signal and power supply device of the tower-top base station according to the present invention configured as described above is first modulated by interfacing the transmission signal from the base station controller and the base station control and interface unit 110 in the indoor device 100 during the forward link. Input to demodulator 120.

The modulation and demodulation unit 120 transmits the input transmission signal to the transceiver 130 by encoding, interleaving, and QPSK modulation, and the transceiver 130 transmits an input 4.95Mhz transmission intermediate frequency signal of 800Mhz digital. Uplink to the cellular system band or the personal mobile communication system band of 1.8Ghz and applied to the line loss compensation unit 140.

The line loss compensator 140 amplifies the applied transmission signal and adds a DC power to the amplified signal and outputs the DC signal.

Here, the line loss compensator 140 includes a variable attenuator 141 which attenuates an input transmission signal by a line loss compensation value as shown in FIG. 5; An amplifier (142) for amplifying the transmission signal attenuated by the variable attenuator (141) to a predetermined level; An inductor (L2) for receiving a DC voltage for transmission to the antenna module and preventing a transmission signal output from the amplifier 142 from being transmitted to the DC voltage input side; A capacitor C3 interposed between the inductor L2 and the amplifier 142 to prevent a DC voltage input through the inductor L2 from being transferred to an output terminal of the amplifier 142, and the amplifier ( The power supply unit 143 supplies a bias power to the 142.

The line loss compensator 140 configured as described above first removes the ripple from the bias power source Vbias input from the power supply unit 143 by using the capacitors C1 and C2. The bias power is supplied to the amplifier 142 through L1.

On the other hand, the input signal is attenuated by the variable attenuation level in the variable attenuator 141 and then input to the amplifier 142. In this case, the attenuation level is attenuated by the input signal by transmitting a control signal corresponding to the level to be attenuated by the base station controller (not shown in the drawing) that controls the overall operation of the system through the control signal bus. That is, the variable attenuator 141 attenuates the input signal by the line loss compensation value, that is, serves as a back-off to widen the loss compensation range.

In addition, the amplifier 142 amplifies and outputs the signal through the variable attenuator 141 by a set gain. The amplified transmission channel signal is combined with a DC voltage transmitted through the inductor L2 and output to the transmission line. . In this case, the capacitor C3 prevents the DC power applied through the inductor L2 from being transmitted to the output terminal of the amplifier 142.

The transmission channel signal transmitted through the transmission line is power amplified by the main amplifier 210 in the outdoor device 200 and is radiated in the space at a desired beam width through the radiation module 220.

Next, in the reverse link, the copy module 220 in the outdoor device 200 receives the transmission signal transmitted from the subscriber and converts the signal into a CDMA reverse channel signal. The converted CDMA reverse channel signal is a low noise amplifier. Amplified in a state of minimizing the noise level at 230, and flows into the indoor device 100 through the receiving line.

The transceiver 130 in the indoor device 100 down-converts the incoming CDMA reverse channel signal to an intermediate frequency of 4.95 MHz, and the down-converted CDMA reverse channel signal is decoded, deinterleaved, by the modulation and demodulation unit 120. After the QPSK demodulation is performed, it is transmitted to the base station controller through the interface function of the base station control and interface unit 110.

6 is another embodiment of the present invention, in which the line loss compensation unit as shown in FIG. 5 is implemented by redundancy.

As shown, the first line loss compensator 310 is provided in the indoor device 100, combines the transmission signal and the DC voltage output from the transceiver 130, and compensates the line loss of the transmission signal in advance. ), The first power supply 320 supplying the driving power to the first line loss compensator 310, and the power supplied from the first power supply 320 and the reference voltage Vref. A comparator 330 for generating a selection signal for selecting a transmission signal as a result value, a combination of a transmission signal and a DC voltage provided in the indoor device 100 and output from the transceiver 130, and the transmission signal The second line loss compensator 340 for compensating for the line loss in advance, the second power supply unit 350 for supplying driving power to the second line loss compensator 340, and the comparator 330 The first and the first according to the selection signal output; It consists of a transmission signal selector 360 for selecting and outputting one of the transmission signals respectively output from the two line loss compensators 310 and 340.

In the above description, the first line loss compensator 310 may amplify a variable attenuator 311 that attenuates an input transmission signal by a line loss compensation value and amplify the transmission signal attenuated by the variable attenuator 311 to a predetermined level. An inductor (L2), an inductor (L2) and an inductor (L2) for receiving a DC voltage for transmission to the antenna module, the amplifier module 312 and preventing the transmission signal output from the amplifier 342 from being transmitted to the DC voltage input side; Interposed between the amplifier 312 is composed of a capacitor (C3) to prevent the DC voltage input through the inductor (L2) to be transmitted to the output terminal of the amplifier 312.

The second line loss compensator 340 also amplifies the variable attenuator 341 that attenuates the input transmission signal by a line loss compensation value and amplifies the transmission signal attenuated by the variable attenuator 341 to a predetermined level. An inductor (L4), an inductor (L4), an inductor (L4) for receiving a DC voltage for transmission to the antenna module and preventing a transmission signal output from the amplifier 342 from being transmitted to the DC voltage input side; Interposed between the amplifier 342 is composed of a capacitor (C6) to prevent the DC voltage input through the inductor (L4) to be transmitted to the output terminal of the amplifier 342.

According to the embodiment of the present invention configured as described above, as shown in FIG. 4, the transmission channel signal sequentially passes through the base station control and interface unit 110, the modulation and demodulation unit 120, and the transceiver 130. The second line loss compensators 310 and 340 are respectively input.

Accordingly, the first line loss compensator 310 attenuates the input transmission signal with the variable attenuator 311 according to the attenuation level and inputs it to the amplifier 312. Here, the attenuation level is attenuated by the input signal by transmitting a control signal corresponding to the level to be attenuated by the base station controller (not shown in the drawing) that controls the overall operation of the system through the control signal bus.

In addition, the amplifier 312 amplifies and outputs the signal through the variable attenuator 311 by a set gain, and the amplified transmission channel signal is combined with the DC voltage transmitted through the inductor L2 and output to the transmission line. . In this case, the capacitor C3 prevents the DC power applied through the inductor L2 from being transmitted to the output terminal of the amplifier 312.

In addition, the second line loss compensator 340 also attenuates the input transmission signal with the variable attenuator 341 according to the attenuation level, similarly to the first line loss compensator 310, and then the amplifier 342. Type in Here, the attenuation level is attenuated by the input signal by transmitting a control signal corresponding to the level to be attenuated by the base station controller (not shown in the drawing) that controls the overall operation of the system through the control signal bus.

In addition, the amplifier 342 amplifies and outputs the signal through the variable attenuator 341 by the set gain, and the amplified transmission channel signal is combined with the DC voltage transmitted through the inductor L4 and output to the transmission line. . The capacitor C6 prevents the DC power applied through the inductor L4 from being transferred to the output terminal of the amplifier 342.

In other words, since the first and second power supply units 320 and 350 also operate in the same manner as the power supply unit 143 of FIG. 5, detailed operations thereof will be omitted.

The comparator 330 divides the voltage supplied from the first power supply 320 into the divided resistors R1 and R2, and the divided voltage and the reference voltage Vref set by the variable resistor 331. ) Is compared with the comparator 332, and a selection signal for selecting the line loss compensation value as a result is generated and input to the transmission signal selection unit 360.

That is, a voltage value of Vcom is set to the inverting terminal (-) of the comparator 332 in the comparator 330 by dividing the current of Ibias + Icom by the voltage divider resistor R1 (R2). If the amplifier 312 in the one-line loss compensator 310 operates abnormally or a failure occurs, the current Ibias is reduced. Therefore, Icom increases, and as the voltage drop caused by the resistor R2 increases, Vcom increases relatively. In this case, the Vcom input to the inverting terminal (-) becomes larger than the reference voltage Vref input to the non-inverting terminal (+) of the comparator 332 so that the comparator 332 generates a high signal.

The high signal generated in this way is input to the transmission signal selector 360. Accordingly, the transmission signal selector 360 selects a signal output from the second line loss compensator 340 input to In1 and transmits the transmission channel. Output as a signal.

That is, when the signal output from the comparator 330 is a low signal, the transmission signal selector 360 determines that the first path f is normal and selects the signal of the first path f. When the signal output from the comparator 330 is a high signal, the signal of the second path f 'is selected and output as a transmission signal.

As described above, the present invention provides a base station system design by integrating a preliminary amplifier and a bias-T (signal and power combiner) into one when installing a tower-top antenna, and compensating for line loss using an MMIC amplifier. It is easy to implement the city circuit, and there is an effect that can compensate the line loss.

In addition, by providing a line loss compensation unit for compensating for the line loss in a predetermined position of the indoor device, there is an advantage that easy maintenance and repair.

Claims (5)

Base station control and interface section, modulation and demodulation section. A tower-top base station apparatus comprising an indoor device composed of a transceiver and an outdoor device formed of a main amplifier, a radiation module, and a low noise amplifier connected to the indoor device through a line. And a line loss compensation means provided in the indoor device and configured to combine a transmission signal and a DC voltage output from the transceiver, and to compensate the line loss of the transmission signal in advance and transmit the line loss to the line. Signal and power supply for tower base stations. 2. The apparatus of claim 1, wherein the line loss compensation means comprises: a variable attenuator for attenuating an input transmission signal by a line loss compensation value; An amplifier for amplifying the transmission signal attenuated by the variable attenuator to a predetermined level; An inductor receiving a DC voltage for transmission to an antenna module and preventing a transmission signal output from the amplifier from being transmitted to the DC voltage input side; A tower interposed between the inductor and the amplifier to prevent a DC voltage input through the inductor from being transmitted to an output terminal of the amplifier, and a voltage supply unit configured to supply a bias voltage to the amplifier. Signal and power supply for tower base stations. Base station control and interface section, modulation and demodulation section. A tower-top base station apparatus comprising an indoor device composed of a transceiver and an outdoor device formed of a main amplifier, a radiation module, and a low noise amplifier connected to the indoor device through a line. A first line loss compensator provided in the indoor device, combining a transmission signal and a DC voltage output from the transceiver and compensating for the line loss of the transmission signal in advance; A first power supply unit supplying driving power into the first line loss compensation unit; A comparison unit for comparing the power supplied from the first power supply unit with a reference voltage and generating a selection signal for selecting a transmission signal as a result value; A second line loss compensator provided in the indoor device, combining a transmission signal and a DC voltage output from the transceiver, and compensating for the line loss of the transmission signal in advance; A second power supply unit supplying driving power into the second line loss compensation unit; And a transmission signal selector configured to select and output one of transmission signals respectively output from the first and second line loss compensators according to the selection signal output from the comparator. And power supply. The apparatus of claim 3, wherein the first and second line loss compensators include: a variable attenuator configured to attenuate an input transmission signal by a line loss compensation value; An amplifier for amplifying the transmission signal attenuated by the variable attenuator to a predetermined level; An inductor receiving a DC voltage for transmission to an antenna module and preventing a transmission signal output from the amplifier from being transmitted to the DC voltage input side; And a capacitor interposed between the inductor and the amplifier and configured to prevent a DC voltage input through the inductor from being transferred to an output terminal of the amplifier. The display device of claim 3, wherein the comparison unit compares a voltage divider resistor for dividing the voltage supplied from the first power supply unit, a voltage divided by the voltage divider resistor, and a reference voltage set by a variable resistor. Signal and power supply of the tower-top base station, characterized in that for generating a selection signal for selecting the output signal of the first and second line loss compensation unit.