KR100983517B1 - Power amplifier for improving output signal in eebts - Google Patents

Abstract

PURPOSE: A power amplifier for improving output signal in a base station is provided to expand a coverage area with low costs by developing a 42.4W Quad PA with a 84.8W Quad PA. CONSTITUTION: A power splitter(102) is comprised of a driver amp and a power divider. A power amplifier(104) outputs amplified signals through a carrier AMP and a peaking AMP. The power amplifier amplifies the signal which is inputted to a power module in 84.8W of 4 channels. A combiner(106) combines the amplified RF signals with one signal to generate an output signal. An output module(108) transmit an RF signal corresponding to the output signal to an antenna through a low-pass filter.

Description

High-power power amplifier for improving base station output {POWER AMPLIFIER FOR IMPROVING OUTPUT SIGNAL IN EEBTS}

The present invention relates to a power amplifier (PA) of a TETRA and IDEN TRS base station system using a digital TRS communication method, and more particularly, a base station system (EEBTS-Enhanced) to enhance shadow area reinforcement and coverage at a low investment cost. Base Transceiver System) The present invention relates to a high output power amplifier for improving the output of a base station to increase the output of a power amplifier (PA) unit of a base radio (BR).

In general, a power combiner used in a mobile communication base station is composed of a divider, a high power linear amplifier (LPA), and a synthesizer in various structures. That is, there may be one divider, one LPA, and a synthesizer for each sector, or two or more. However, if there is one divider, high output linear amplifier (LPA), and synthesizer for each sector (single path), if there is an error in the module or device, the output is not possible because it is impossible to transmit. High power is often required, so it is common to use a power combiner with multiple paths per sector.

The conventional power combiner represents an n-way type power combiner for each sector, which is composed of several high power linear amplifiers (LPAs) that amplify a weak signal and produce a large output signal. To produce larger output. That is, the input signal is separated through a divider that divides the input signal into several paths, and each of the separated path signals is input to an input terminal of a high output linear amplifier (LPA). Then, each high output linear amplifier LPA amplifies each path signal and amplifies and outputs the path signal to the LPA output terminal.

Then, each amplified path signal is combined through a synthesizer element to produce a larger output to produce a single high output signal. In the structure of the conventional power combiner that generates such a high output signal, the path signals separated by respective paths in the divider are amplified while passing through the high output linear amplifier (LPA), and output the respective amplified path signals to the output stage. In the amplification step, a difference in voltage (current) level and phase is generated between output path signals due to the internal structure of each of the high power linear amplifiers (LPAs).

As such, each of the high power linear amplifiers (LPAs) will show differences in their internal structures due to manufacturing or design differences, and they will all have slight differences in input / output relationships. Therefore, the path signals of the LPA output stages are different in phase and level from each other, which causes a problem of generating power loss when synthesized in the synthesizer device. As a result, according to the conventional power combiner, if the amplification characteristics are different between the LPAs of the same maker as well as the manufacturers of the high power linear amplifiers (LPA), a fatal loss occurs and the need to tune again (Tuning) The problem arises, and there is a double problem that can not be used in combination due to the constraint that the high power linear amplifiers (LPA) cannot be used together.

On the other hand, the high power linear amplifier (LPA) also designs the structure in consideration of FA scalability, but the combiner that combines / distributes the signals input and output to the high output linear amplifier (LPA) increases the number of users of the EBTS or omits the sector type EBTS. OMNI) type EBTS, when omni type EBTS is changed to sector type EBTS, the system can be operated only by replacing with a combiner suitable for FA considering the purpose of use. In other words, the combiner only has to replace the existing combiner with the corresponding combiner shelf, not the additional implementation. Therefore, if a change in EBTS capacity is required to combine the high power linear amplifier (LPA) output, this high power linear amplifier (LPA) combiner must be replaced with the appropriate type, and again if there is a change in capacity, the combiner It must be replaced accordingly.

Therefore, operators have to pay a significant portion of the additional cost for replacing a high power linear amplifier (LPA) or combiner, which is a significant economic burden for operators operating thousands of EBTS. Furthermore, there is a problem in that the EBTS must bear the loss of service while the combiner replacement work is in progress.

The present invention was created to solve the above problems, and an object of the present invention is to expand coverage at a low cost, improve base station operation efficiency, and improve output degradation due to the use of a quad BR, thereby providing shadow area and short-range services. It is to provide a high output power amplifier for the base station output enhancement that can be expanded.

Another object of the present invention, by providing a high output power amplifier that can double the output of the Quad BR using only DC power less than 500W, for improving the base station output to continue to use the existing power supply It is to provide a high output power amplifier.

Still another object of the present invention is to provide a high output power amplifier for improving base station output, which can realize a low cost and high efficiency by providing a service area of about twice as much as the coverage distance is increased by 1.4 times by increasing the output increase to 3 dB. Is in.

According to an aspect of the present invention for achieving the above object, a high output power amplifier for improving a base station output power, which is divided into a plurality of output signals in a high output power amplifier of a base station system (EBTS) BR (Base Radio). A power splitter for receiving the RF signal and distributing the RF signal into an RF1 signal as a reference signal and an RF2 signal as a 90 degree phase difference signal of the RF1 signal through a plurality of signal distributors; The power splitter is based on a plurality of Doherty amplifiers outputting an amplified signal RF1A obtained by power amplifying the RF1 signal by a carrier amplifier and a peaking amplifier, and outputting an amplified signal RF2A obtained by power amplifying the RF2 signal. A power amplifier (PA) for changing a phase so that a plurality of output signals from the plurality of output signals are not affected by each module signal, and amplifying the signal to a power output of 4 channels of 84.8W through a high output device when a signal is input to the power module; A combiner for generating an output signal by combining the RF signals RF1A and RF2A amplified to the predetermined level for each path from the power amplifier into one signal; An output module which transmits an RF signal corresponding to the output signal to an antenna via a low pass filter, and couples the RF signal to a front end of the power splitter to induce a stable output; And a control module for checking a state of the output module and operating a system according to a processing algorithm for each state.

Preferably, the Doherty amplifier receives the RF1 signal or the RF2 signal distributed by a power splitter and distributes the RF1 signal or RF21 signal as an RF12 signal or RF22 signal that is a 90 ° phase difference signal between the RF11 signal or RF21 signal and the RF11 signal or RF21 signal. A Doherty signal splitter; A first input matching circuit for input matching the RF11 signal or RF21 signal distributed by the Doherty signal splitter, and a second input matching circuit for input matching the RF12 signal or RF22 signal distributed by the Doherty signal splitter An input matching unit; A carrier amplifier for power amplifying the input matched RF11 signal or RF21 signal and outputting the amplified signal RF11A or RF21A, and amplified signal RF12A or RF22A by power amplifying the input matched RF12 signal or RF22 signal. An amplifier configured to output a peaking amplifier; An output matching circuit including a first output matching circuit for output matching the power amplified signal RF11A or RF21A and a second output matching circuit for output matching the power amplified signal RF12A or RF22A; A phase compensator including a first transmission line for compensating the phase of the output matched signal RF11A or RF21A and a second transmission line for compensating the phase of the output matched signal RF12A or RF22A; And a λ / 4 delay line for delaying the phase compensated reference signal RF11A or RF21A by 90 ° so that the phase compensated signal RF11A or RF21A and the signal RF12A or RF22A are coupled in phase. In order to convert the output impedance of the signal RF1A or RF2A coupled in phase with the compensated signal RF12A or RF22A and the delayed signal RF11A or RF21A by the λ / 4 delay line, connected in parallel, Characterized in that it consists of an impedance conversion circuit consisting of a winding inductor connected in series between the two chip capacitors and the two chip capacitors.

The high output power amplifier for improving base station power presented in the present invention, by developing / applying an existing 42.4W Quad PA as an 84.8W Quad PA, expands coverage at a low cost, increases base station operation efficiency, and improves the Quad BR. It is possible to expand shadow area and short-range service by improving output reduction by using mixed.

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

First, Figure 1 is a block diagram showing a high output power amplifier according to the present invention. As shown, the high output power amplifier receives an input signal RF 112 which is divided into a plurality of output signals, and receives the RF signal RFin as a reference signal and the RF1 signal through a plurality of signal splitters. Outputting an amplified signal RF1A obtained by power amplifying the RF1 signal by a power amplifier and a picking amplifier, and a power splitter 102 for distributing the RF2 signal as a 90-degree phase difference signal Based on a plurality of Doherty amplifiers outputting (RF2A), when a signal is input to the power module by changing the phase so that the plurality of output signals from the power splitter 102 are not affected by each module signal, A power amplifier (PA) 104 which amplifies to 44.8W output of 4 channels through a high output device, and RF signals (RF1A, RF2A) amplified to a predetermined level for each path from the power amplifier (104) one The combiner 106 combines the signal to generate an output signal 114, and transmits an RF signal corresponding to the output signal 114 to the antenna via a low pass filter. Coupling (Coupling) the output module 108 to induce a stable output by transmitting to the front end of the power splitter 102, and a control module for checking the status of the output module and operating the system according to the processing algorithm for each state Consists of 110.

The plurality of Doherty amplifiers may include first, third and fifth Doherty amplifiers 131, 133 and 135 for amplifying the RF1 signal, and second, fourth and six Doherty amplifiers 132, 134 for amplifying the RF2 signal. , 136).

In addition, the power splitter 102 branches a driver amplifier for first amplifying the input signal 112 and an RF signal amplified through the driver amplifier in various paths to the power amplifier 104. It includes a power divider provided by. Here, the power splitter 102 divides the input RF input signal 112 into three two-path signals and provides them to the power amplifier 104.

Therefore, the power amplifier 104 is provided with six pairs of power amplifiers, and the six pairs of power amplifiers have a performance of up to 85W output power, and the power transistors applied thereto are used by six 'MRF6P 9220' transistors. do. Of course, it will be appreciated that the power transistor presented in the present invention may be replaced by another element of the same specification. The power amplifier 104 configured as described above is a quad power amplifier in which 12 are configured in parallel by forming six pairs and transmitting four-channel RF signals. The quad power amplifier then transmits about 84.8W of output power per four channels, thus outputting about 21.2W of power per channel.

2 is a block diagram illustrating a Doherty amplifier of the power amplifier 104 according to the present invention.

As shown, the Doherty amplifier includes a Doherty signal divider 201, an input matcher 210, an amplifier 220, an output matcher 230, a phase compensator 240, and a λ / 4 delay line 250. And an impedance conversion circuit 260. In the case of the first Doherty amplifier 131, the signal RFi input to the Doherty signal divider 201 is an RF1 signal distributed by a power divider of the wave splitter 102, and a second Doherty amplifier. In the case of the amplifier 132, the signal RFi input to the Doherty signal divider 201 is an RF2 signal distributed by the power divider of the wave splitter 102.

In the Doherty amplifier configured as described above, when the RF1 signal or the RF2 signal is input, the Doherty signal splitter 201 is an RF12 signal or an RF12 signal that is a 90 degree phase difference signal between the RF11 signal or the RF21 signal and the RF11 signal or the RF21 signal. It is distributed by RF22 signal. The RF11 signal or the RF21 signal, which is the reference signal, is a signal that is inputted to the Doherty signal divider 201 by a phase delay of 90 degrees and output. The RF12 signal or the RF22 signal is a signal in which the RF1 signal or the RF2 signal is input to the Doherty signal splitter 201 and is 180 degrees out of phase. Therefore, there is a phase difference of 90 degrees between the RF11 signal or the RF21 signal and the RF12 signal or the RF22 signal.

On the other hand, the input matching unit 210 by the first input matching circuit 211 and the Doherty signal splitter 201 for input matching the RF11 signal or RF21 signal distributed by the Doherty signal splitter 201 And a second input matching circuit 212 for input matching the distributed RF12 signal or RF22 signal. The amplifier 220 includes a carrier amplifier 221 for power amplifying the input matched RF11 signal or RF21 signal, and a peaking amplifier 222 for power amplifying the input matched RF12 signal or RF22 signal. In addition, the carrier amplifier 221 and the picking amplifier 222 may be implemented as a push-pull laterally diffused MOSFET (LDMOSFET). The output matching unit 230 may include a first output matching circuit 231 for output matching the power amplified signal RF11A or RF21A, and a second output for matching the power amplified signal RF12A or RF22A. And a matching circuit 232.

The phase compensator 240 includes a first transmission line 241 for compensating the phase of the output matched signal RF11A or RF21A and a second compensating phase of the output matched signal RF12A or RF22A. It consists of a transmission line 242. The λ / 4 delay line 250 is a phase of the phase compensated signal RF11A or RF21A such that the phase compensated signal RF11A or RF21A and the phase compensated signal RF12A or RF22A are coupled in phase. Phase delay by 90 degrees. The impedance 2 conversion circuit 260 outputs a signal RF1A or RF2A to which the phase compensated signal RF12A or RF22A and the signal RF11A or RF21A which are delayed by the λ / 4 delay line 250 are combined. In order to convert the impedance into a 50 ohm characteristic impedance, a wired inductor 263 is connected in series between two chip capacitors 261 and 262 connected in parallel and the two chip capacitors 261 and 262.

In the case of the Doherty amplifier which amplifies a low frequency signal by implementing the impedance conversion circuit 260 as a lumped constant element such as the wound inductor 263 and the chip capacitors 261 and 262, rather than the microstrip line. The amplifier size can be further miniaturized.

Meanwhile, as described above, each output signal RF0 of the Doherty amplifiers 131 to 136 is applied to the power combiner 106. That is, as shown in FIG. 3, the power combiner 106 is an input node 301 which receives respective signals RF01 and RF02 output from the Doherty amplifiers 131 to 136, and the respective inputs. A plurality of phase transmission lines 303, a plurality of matching transmission lines 305, and a common node 307 connected to the node 301 are included.

The input node 301 is coupled with each Doherty amplifier 131-136 in the power amplifier 104, and each phase transmission line 303 is connected to one of the input nodes 301 at one end and the other At the end is connected to one of the matching transmission lines 305. Each phase transfer line 303 also has a characteristic impedance that is substantially equal to the output load. For example, because the output load has an impedance of 50Ω as described above, each phase transfer line has a characteristic impedance of about 50Ω.

Further, each phase transmission line 303 has a length equal to λ / 4, and each matching transmission line 305 is connected to a common node 307. And each matching transmission line 305 has a length equal to [lambda] / 4 or an odd multiple thereof. Furthermore, each matching transmission line 305 has a characteristic impedance determined as a function of the minimum and maximum number of amplifiers among the Doherty amplifiers 131-136 of the power amplifier 104. Here, the function is a nonlinear function, which is the square root of the product of the minimum number of amplifiers and the maximum number of amplifiers, multiplied by the load impedance 128.

However, other nonlinear functions, such as the square root, may also provide adequate performance, although not as optimal as the square root function, such a relationship is adjacent to the matching transmission line 305. The common node 307 is connected to each of the matching transmission lines 305, and is also connected to the output module 108 having a normal 50Ω.

Thereafter, the output module 108 transmits the output signal 114 output from the power combiner 106 to the antenna through a low pass filter. In addition, the Forward / Reverse Detector and the RF signal are coupled to the circuit (Coupling) to feed back to the EX / CNTL B / D (Exciter / Controller Base Radio) installed in the previous step of the power splitter (102). At this time, in the process of detecting the output signal level and sending it to the installed EX / CNTL B / D (Exciter / Controller Base Radio), the actual output level is 84.8W, but it is output by inserting a pad (special resistor) to be recognized as 42.4W. Reduce it so that it recognizes the same output level as before. That is, the actual detected signal is recognized as the existing 42.4W and provided to EX / CNTL B / D (Exciter / Controller Base Radio). The control module 110 also checks the status of each module, detects various alarms, and performs status reporting and processing procedures with the EX / CNTL B / D.

As described above, the high output power amplifier according to the present invention provides a pallet considering the linearity and efficiency of the power amplifier 104 to double the output of the existing PA. In addition, an appropriate adjustment of the amplitude and phase of the amplifier transfer function is achieved, resulting in an 84.8 W QUAD BR. 4 illustrates a system specification of a high output power amplifier according to the present invention, and FIG. 5 illustrates an output value of a quad BR of the high output power amplifier based on the system specification. This increases the coverage by 1.4 times (distance), which improves the existing 42.4W = 46.27dBm output level to 84.8W = 49.28dBm, resulting in a 3.01dB increase in output. In other words, a 3.01dB increase in PathLoss increases coverage by 1.41x.

As described above, the high output power amplifier according to the present invention proposes a pallet considering the gain, linearity, and efficiency of the main amp to double the output of the existing PA, and the BR DC power supply capacity is 500W (below 575W) By designing less than Max 17A / 28.8V), the 42.4W Quad PA can be provided as an 84.8W Quad PA, which enables coverage to be expanded at a lower cost, improving efficiency in base station operation, and improving the facilities of the base station system. We believe the value will increase sufficiently.

1 is a block diagram showing a high output power amplifier according to the present invention.

FIG. 2 is a diagram illustrating a heater amplifier of the power amplifier PA of FIG. 1.

3 is a view for explaining the function of the power combiner of FIG.

4 is a diagram showing a system specification of a high output power amplifier according to the present invention.

5 is a view showing an output result of the present invention according to the standard of FIG.

<Explanation of symbols for main drawings>

102: power splitter 104: power amplifier (PA)

106: power combiner 108: output module

110: control module 112: input signal

114: output signal 201: Doherty signal splitter

210: input matching unit 220: amplification unit

230: output unit 240: phase compensation unit

250: delay line 260: impedance conversion circuit

Claims (11)

In the high output power amplifier of the base station system (EBTS) BR (Base Radio), Based on a driver amplifier (MP) that receives an input signal (RF) 112 divided into a plurality of output signals and amplifies it first, and an RF signal amplified by the driver amplifier based on a plurality of signal distributors A power splitter (102) comprising a power divider for distributing an RF1 signal, which is a signal, and an RF2 signal, which is a 90 degree phase difference signal of the RF1 signal; Based on a plurality of Doherty amplifiers 131-136 outputting an amplified signal RF1A obtained by power amplifying the RF1 signal by a carrier amplifier and a peaking amplifier, and outputting an amplified signal RF2A obtained by power amplifying the RF2 signal. When a signal is inputted to the power module by changing the phase so that a plurality of output signals provided from the power splitter 102 are not affected by each module signal, the output signal is output to 4 channel 84.8W through the high output device. A power amplifier (PA) for amplifying; A combiner 106 for generating an output signal 114 by combining the RF signals RF1A and RF2A amplified to a predetermined level for each path from the power amplifier 104 into one signal; The RF signal corresponding to the output signal 114 is transmitted to the antenna via a low pass filter, and the RF signal is coupled to the front end of the power splitter 102 by coupling the RF signal to transmit a stable output. Inducing output module 108; And A high output power amplifier for improving the output of the base station, characterized in that the control module 110 for checking the state of the output module and operating the system according to the processing algorithm for each state. The method of claim 1, The plurality of Doherty amplifiers include first, third, and fifth Doherty amplifiers 131, 133, and 135 that amplify the RF1 signal, and second, fourth, and sixth Doherty amplifiers 132, 134, and 136 that amplify the RF2 signal. High output power amplifier for improving the output of the base station comprising a. delete The method of claim 1, The power splitter (102) is a high output power amplifier for improving the base station output, characterized in that for providing the power amplifier (104) by distributing the three RF signal input signal (112). The method of claim 1, The power amplifier 104 is a quad power amplifier that transmits a four-channel RF signal, the power transistor is applied to the high power power amplifier for the base station output, characterized in that the 'MRF6P 9220' element is used. The doherty amplifier of claim 1 or 5, Doherty which receives the RF1 signal or RF2 signal distributed by the power divider and distributes the RF1 signal or RF21 signal, which is a reference signal, to the RF12 signal or RF22 signal, which is a 90 ° phase difference signal between the RF11 signal or RF21 signal. Signal splitter 201; A first input matching circuit 211 for input matching the RF11 signal or RF21 signal distributed by the Doherty signal splitter 201, and the RF12 signal or RF22 signal distributed by the Doherty signal splitter 201. An input matching unit 210 including a second input matching circuit 212 for matching; A carrier amplifier for power amplifying the input matched RF11 signal or RF21 signal and outputting the amplified signal RF11A or RF21A, and amplified signal RF12A or RF22A by power amplifying the input matched RF12 signal or RF22 signal. An amplifier 220 composed of an output peaking amplifier; An output including a first output matching circuit 231 for output matching the power amplified signal RF11A or RF21A, and a second output matching circuit 232 for output matching the power amplified signal RF12A or RF22A. Matching unit 230; A phase composed of a first transmission line 241 compensating for the phase of the output matched signal RF11A or RF21A, and a second transmission line 242 compensating for the phase of the output matched signal RF12A or RF22A A compensation unit 240; And A λ / 4 delay line that delays the phase compensated reference signal RF11A or RF21A by 90 ° so that the phase compensated signal RF11A or RF21A and the signal RF12A or RF22A are coupled in phase, and the phase compensation A parallel connection to convert the output impedance of the combined signal RF12A or RF22A and the signal RF11A or RF21A delayed by the λ / 4 delay line into a 50-ohm characteristic impedance A high output power amplifier for improving base station output, comprising an impedance conversion circuit (260) consisting of two chip capacitors (261, 262) and a wound inductor (263) connected in series between the two chip capacitors. The method of claim 1, The power combiner 106 is an input node 301 for receiving the respective signals RF01 and RF02 output from the Doherty amplifiers 131 to 136, and a plurality of input nodes 301 connected to the input node 301. A high output power amplifier for base station output enhancement comprising a phase transmission line (303), a plurality of matching transmission lines (305) and a common node (307). The method of claim 7, wherein The input node 301 is coupled with each Doherty amplifier 131-136 in the power amplifier 104, and each phase transmission line 303 is connected to one of the input nodes 301 at one end and the other At the end, connected to one of the matching transmission lines 305, each phase transmission line 303 having a characteristic impedance substantially equal to the output load. The method of claim 8, And said output load and each phase transmission line (303) have an impedance of 50 ohms. 10. The method according to claim 8 or 9, Each phase transmission line 303 has a length equal to a quarter wavelength, and each matching transmission line 305 is connected to a common node 307. A high output power amplifier for base station output enhancement. The method of claim 10, Wherein each matching transmission line (305) has a length equal to a quarter wavelength or an odd multiple thereof.

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