KR20090090684A - Power amplifier for digital trs base station - Google Patents

Abstract

A power amplifier of a digital TRS base station is provided to expand a service region and to improve communication service quality of a digital TRS(Truncated Radio System) base station by performing a power amplifier through a Doherty amplifier which generates a high output. A first signal distributor(110) distributes an input RF signal. A second signal distributor distributes the input RF signal distributed by the first signal distributor into a RF 1 signal and a RF 2 signal. The RF 1 signal is a reference signal. The RF 2 signal has a phase difference of 90 degree from the first RF 1 signal. A first Doherty amplifier amplifies the distributed RF 1 signal by a carrier amplifier and a peaking amplifier, and outputs a first signal(RF1A). A second Doherty amplifier amplifies the distributed RF 2 signal by the carrier amplifier and the peaking amplifier, and outputs a second signal(RF2A). A first signal combiner(141) combines the first signal amplified by the first Doherty amplifier and the second signal amplified by the second Doherty amplifier as signals of the same phase. A second signal combiner(150) outputs a signal combined by the first signal combiner.

Description

Power Amplifier for Digital TRS Base Stations

The present invention relates to a digital TRS (Truncated Radio System) base station, and more particularly, to a power amplifier of a digital TRS base station implemented by a plurality of Doherty amplifiers that increase power efficiency to generate high power output.

1 shows an example of a conventional power amplifier configuration used in a digital TRS base station.

As shown in FIG. 1, a conventional power amplifier includes a three-path signal divider 11, a plurality of two-path signal dividers 21, 22, and 23, and a plurality of two-path signal dividers 21, 22, and 23. A plurality of power amplifiers connected in parallel to each of the plurality of two-path signal splitters 21, 22, and 23 are paired power amplifiers that simultaneously receive and simultaneously amplify a radio frequency (RF) signal distributed from the plurality of two-path signal distributors. (31a, 31b, 32a, 32b, 33a, 33b, 34a, 34b, 35a, 35b, 36a, 36b), and a plurality of signal combiners 41, 42, which combine RF signals amplified in two pairs of power amplifiers, respectively. 43) and a signal combiner 51 for combining and outputting each RF output signal coupled by the plurality of signal combiners 41, 42, and 43 into one RF output signal.

The three-path signal divider 11 divides the RF input signal into three paths and provides them to three two-path signal dividers 21, 22, and 23.

Each of the two-path signal dividers 21, 22, and 23 divides the RF input signal distributed from the three-path signal divider 11 into two paths, respectively, so that six pairs of power amplifiers 31a, 31b, 32a, 32b, 33a, 33b, 34a, 34b, 35a, 35b, 36a, and 36b. The six pairs of power amplifiers 31a, 31b, 32a, 32b, 33a, 33b, 34a, 34b, 35a, 35b, 36a, and 36b are arranged in parallel with six pairs of 12 transistors having a performance of 45W output power. It is composed.

The power amplifier of the conventional base station configured as described above is a quad power amplifier for transmitting four-channel RF signal. The quad power amplifier actually transmits about 42.4W of output power per four channels, thus outputting about 10.6W of output power per channel.

In general, a base radio is used to provide a mobile communication service in a digital TRS base station. The base radio is a conventional power amplifier configured as described above, and a power supply for supplying power to the power amplifier. 1), and a control unit (not shown in FIG. 1) for controlling the operation of the power amplifier.

In addition, there are various types of base radios used in base stations. That is, there is a base radio using a quad power amplifier that transmits a signal of four channels shown in FIG. 1, and a base radio using a 40 W single power amplifier and a 70 W single power amplifier that transmits a single channel signal. There may be.

Currently, the conventional quad power amplifier shown in Fig. 1 outputs 10.6W of output power per channel, whereas a 40W single power amplifier can output 40W output power per channel and a 70W single power amplifier outputs 70W per channel. It can output power.

When the base station uses a combination of the above-described power amplifiers having different output power levels, the output power of the quad power amplifier shown in FIG. 1 is the lowest and thus the channel of the 70W single power amplifier having a relatively high channel output power. Because the communication is concentrated, the call quality decreases and the efficiency of the base station decreases.

In addition, when only the conventional quad power amplifier shown in FIG. 1 is used in the base station, the conventional quad power amplifier is low in power efficiency and low in output power, and thus the cost must be replaced by a larger capacity power supply to increase the output power. And problems such as heat dissipation, and thus are not easy to increase the subscriber capacity of the base station.

Accordingly, an object of the present invention is to solve the above problems, and an object of the present invention is to implement a power amplifier using a Doherty amplifier generating high efficiency and high efficiency, thereby improving communication service quality of a digital TRS base station and expanding a service area. To provide a power amplifier of a digital TRS base station that can be.

In order to achieve the above object, a power amplifier of a digital TRS base station according to the present invention comprises: a first signal distributor for distributing an input RF signal RFin; A second signal splitter for distributing an input RF signal RFin distributed by the first signal splitter into an RF1 signal that is a reference signal and an RF2 signal that is a 90 ° phase difference signal of the RF1 signal; A first Doherty amplifier for power amplifying the distributed RF1 signal by a carrier amplifier and a picking amplifier and outputting the amplified signal RF1A, and a signal amplified by power amplifying the distributed RF2 signal by a carrier amplifier and a peaking amplifier A Doherty amplifier having a second Doherty amplifier for outputting (RF2A) configured in parallel; A first signal combiner for coupling the signal RF1A amplified by the first Doherty amplifier and the signal RF2A amplified by the second Doherty amplifier into a signal RFout in phase; And a second signal combiner for outputting a signal RFout coupled in phase by the first signal combiner.

In order to achieve the above object, a power amplifier of a digital TRS base station according to the present invention includes a first signal distributor for distributing an input RF signal RFin into a plurality of paths; A plurality of second signal splitters for distributing each of the plurality of input RF signals RFin distributed by the first signal splitter into an RF1 signal as a reference signal and an RF2 signal as a 90 degree phase difference signal of the RF1 signal; A first Doherty amplifier for outputting the amplified signal RF1A by power amplifying each RF1 signal distributed by the plurality of second signal splitters by a carrier amplifier and a picking amplifier, and by the plurality of second signal splitters A plurality of Doherty amplifiers each including a plurality of Doherty amplifiers configured to have a second Doherty amplifier configured to perform power amplification on each of the divided RF2 signals by the carrier amplifier and the picking amplifier and output the amplified signal RF2A; A plurality of first signal combiners for coupling the first signal RF4 and the second signal RF5 amplified by the first Doherty amplifier and the second Doherty amplifier, respectively, connected to each of the plurality of Doherty amplifiers; And a second signal combiner configured to combine and output a signal coupled by each of the plurality of first signal combiners into an RF output signal RFout.

As described above, the present invention implements the power amplifier of the digital TRS base station with a plurality of Doherty amplifiers generating high efficiency and high output, so that the RF signal can be generated with high power output. There is an effect that can improve the service call quality of the digital TRS base station and easily improve the service area without having to expand the area.

In addition, the present invention has the effect of reducing costs by using the existing power supply as it is without increasing the capacity of the additional power supply even in the high power output.

The present invention implements the impedance converter of the Doherty amplifier by using a lumped element such as a wired inductor and a chip capacitor, which enables the miniaturization of the Doherty amplifier, thereby transmitting a digital signal when transmitting an RF signal of a low frequency band. There is an effect that the power amplifier of the TRS base station can be further miniaturized.

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

2 is a configuration diagram of a power amplifier of a digital TRS base station according to an embodiment of the present invention.

As shown in FIG. 2, the power amplifier of the digital TRS base station according to the embodiment of the present invention includes a first signal divider for distributing an input RF signal RFin into a plurality of paths; A plurality of second signal splitters for distributing each of the plurality of input RF signals RFin distributed by the first signal splitter into an RF1 signal as a reference signal and an RF2 signal as a 90 degree phase difference signal of the RF1 signal; A first Doherty amplifier for outputting the amplified signal RF1A by power amplifying each RF1 signal distributed by the plurality of second signal splitters by a carrier amplifier and a picking amplifier, and by the plurality of second signal splitters A plurality of Doherty amplifiers each including a plurality of Doherty amplifiers configured to have a second Doherty amplifier configured to perform power amplification on each of the divided RF2 signals by the carrier amplifier and the picking amplifier and output the amplified signal RF2A; A plurality of first signal combiners for coupling a first signal RF4 and a second signal RF5 amplified by the first Doherty amplifier and the second Doherty amplifier, respectively, connected to each of the plurality of Doherty amplifiers; And a second signal combiner which combines and outputs a signal coupled by each of the plurality of first signal combiners into an RF output signal RFout.

The input RF signal is an RF signal of four channels.

The RF1 signal, which is the reference signal, is a signal whose phase is delayed by 90 degrees by the second signal splitter 121, 122 or 123, and the RF2 signal is input by the second signal splitter 121, 122 or 123. The signal is a phase delayed signal of 180 degrees, and there is a 90 degree phase difference between the RF signal and the RF2 signal.

3 shows a detailed configuration of the Doherty amplifier according to the present invention, and shows a detailed configuration of each of the first Doherty amplifier and the second Doherty amplifiers 131 to 136 of FIG.

The Doherty amplifier according to the present invention 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.

For example, in the case of the first Doherty amplifier 131, the signal RFi input to the Doherty signal distributor 201 is an RF1 signal distributed by the second signal distributor 121, and the second Doherty amplifier 132 is used. In this case, the signal RFi input to the Doherty signal splitter 201 is an RF2 signal distributed by the second signal splitter 121.

When the RF1 signal or the RF2 signal distributed by the second signal splitter 121 of FIG. 2 is input, the Doherty signal splitter 201 illustrated in FIG. 3 may be a reference signal RF11 signal or RF21 signal and the RF11 signal or It divides into RF12 signal or RF22 signal which is a 90 degree phase difference signal of RF21 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.

The input matching unit 210 is distributed by the first input matching circuit 211 and the Doherty signal divider 201 for input matching the RF11 signal or the RF21 signal distributed by the Doherty signal splitter 201. And a second input matching circuit 212 for input matching the RF12 signal or the 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 conversion circuit 260 outputs an output impedance of the signal RF1A or RF2A to which the phase compensated signal RF12A or RF22A and the signal RF11A or RF21A coupled by the λ / 4 delay line 250 are combined. In order to convert a to 50 ohm characteristic impedance, the two wire capacitors 261 and 262 connected in parallel and the winding type inductor 263 connected in series between 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.

Referring to the operation of the power amplifier of the digital TRS base station according to the embodiment of the present invention configured as described above are as follows.

The first signal splitter 110 distributes four input RF signals RFin to three paths and provides them to three second signal splitters 121, 122, and 123, respectively.

Each of the second signal splitters 121, 122, and 123 divides the input RF signal RFin distributed by the first signal splitter 110 into two RF signals having a phase difference of 90 degrees from each other. That is, the second signal splitter 121 divides the divided input RF signal RFin into an RF1 signal, which is a 90 degree phase difference signal between the RF1 signal as a reference signal and the first signal RF1, and divides the RF1 signal into a second signal. The first Doherty amplifier 131 is provided to the second Doherty amplifier 132. The second signal splitter 122 divides the divided input RF signal RFin into an RF1 signal that is a reference signal and an RF2 signal that is a 90 degree phase difference signal between the RF1 signal and distributes the RF1 signal to the first Doherty amplifier 133. Provide the RF2 signal to a second Doherty amplifier 134. The second signal splitter 123 divides the divided input RF signal RFin into an RF1 signal that is a reference signal and an RF2 signal that is a 90-degree phase difference signal between the RF1 signal and divides the first signal RF1 into a first Doherty amplifier. And the RF2 signal to the second Doherty amplifier 136.

Each of the first Doherty amplifiers 131, 133, and 135 of each of the Doherty amplifiers 130 outputs the amplified signals RF1A by power amplifying the RF1 signals respectively distributed in the corresponding second signal distributors 121, 122, and 123. Each of the second Doherty amplifiers 132, 134, and 136 outputs the amplified signals RF2A by power amplifying the RF2 signals distributed by the three second signal distributors 121, 122, and 123, respectively. Detailed operation of each Doherty amplifier 131-136 will be described later.

Each of the first and second Doherty amplifiers 131-136 of each Doherty amplifier 130 consists of a quad Doherty amplifier that transmits 84.8W output power in four channels, thus transmitting 21.2W output power in one channel. do. This generates twice the output power of the output power of the power amplifier of the conventional base station.

The first signal combiner 141 receives the signal RF1A power amplified by the first Doherty amplifier 131 of the Doherty amplifier 130 and the signal RF2A power amplified by the second Doherty amplifier 132. The combined signals RFout are output by combining the phase difference with each other. The first signal combiner 142 exchanges the signal RF1A power amplified by the first Doherty amplifier 133 of the Doherty amplifier 130 and the signal RF2A power amplified by the second Doherty amplifier 134. It combines so that there is no phase difference and outputs the combined signal RFout. The first signal combiner 143 is a signal RF1A power amplified by the first Doherty amplifier 135 of the Doherty amplifier 130 and a second signal RF2A power amplified by the second Doherty amplifier 136. Are combined so that there is no phase difference with each other, and the combined signals RFout are output.

The second signal combiner 150 combines the combined signals RFout output from the three first signal combiners 141, 142, and 143, respectively, and outputs the combined signals RFout as RF output signals RFout.

Digital TRS base station power amplifier according to an embodiment of the present invention is to use the existing power supply as it is without increasing the capacity of the additional power supply (not shown in Figure 2), nevertheless by implementing a high efficiency Doherty amplifier It generates two times the output power of the power amplifier output power.

Now, an operation of one Doherty amplifier, for example, the first Doherty amplifier 131, of the first and second Doherty amplifiers 131 to 136 constituting each Doherty amplifier 130 will be described.

When the RF1 signal distributed by the second signal splitter 121 is input, the Doherty signal splitter 201 phase-delays the first signal RF1 by 90 degrees to phase the RF11 signal and the RF1 signal by 180 degrees. The signal is delayed and distributed to the RF12 signal, which is a 90 degree phase difference signal of the RF11 signal.

The first input matching circuit 211 of the input matching unit 210 input-matches the distributed RF11 signal and outputs it to the carrier amplifier 221 of the amplifier 220, and the second input matching circuit 212 is The distributed RF12 signal is input matched and output to the peaking amplifier 222.

The carrier amplifier 221 of the amplifier 220 receives the input matched RF11 signal, and the peaking amplifier 222 of the amplifier 220 receives the input matched RF12 signal and performs a power amplification operation, respectively. do. Accordingly, the carrier amplifier 221 outputs the power amplified signal RF11A and the peaking amplifier 222 outputs the power amplified signal RF12A.

The signal RF11A amplified by the carrier amplifier 221 is output matched through the first output matching circuit 231 and then transmitted to the first transmission line 241 of the phase compensator 240 and the peaking. The power RF amplified signal RF12A through the amplifier 222 is output matched through the second output matching circuit 232 and then transmitted to the second transmission line 242 of the phase compensator 240.

The first transmission line 241 compensates for the phase of the output matched signal RF11A and the second transmission line 242 compensates for the phase of the output matched signal RF12A, thereby outputting the output matched signal RF11A. ) And a phase difference of 90 degrees between the output matched signal RF12A.

Λ / 4 delay line 250 so that the phase compensated signal RF11A by the first transmission line 241 and the phase compensated signal RF12A by the second transmission line 242 can be combined in phase. ) Delays the phase compensated signal RF11A by 90 degrees with the first transmission line 241.

The impedance conversion circuit 260 composed of two chip capacitors 261 and 262 connected in parallel to each other and a wound inductor 263 connected in series between the two chip capacitors 261 and 262 is phase compensated through a second transmission line 242. The output signal RFo, i.e., the amplified signal, by converting the output impedance of the combined signal RF12A and the signal RF1A coupled by the λ / 4 delay line 250 to the 50 ohm characteristic impedance. Output the signal RF1A. The amplified signal RF1A is input to the first signal combiner 141 shown in FIG. 2.

Thus, 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 size can be further reduced.

As described above, the digital TRS base station power amplifier according to the present invention, which transmits four-channel signals, maximizes power efficiency and outputs twice the power of the conventional quad power amplifier without increasing the capacity of an additional power supply. Therefore, when the base station power amplifier according to the present invention is used in combination with a single power amplifier that transmits a signal in a single channel and has a relatively high output power, the existing power supply may be used as it is without additional capacity increase of the power supply. Since a high power output can be generated from the power amplification device, it is possible to easily increase the service capacity of the base station.

The present invention has been described in detail so far, but the embodiments mentioned in the process are only illustrative and are not intended to be limiting, and the present invention is provided by the following claims and the technical spirit and field of the present invention. Within the scope of not departing from the scope of the present invention, changes in the components that can be coped evenly will fall within the scope of the present invention.

1 is a configuration diagram of a power amplifier of a conventional digital TRS base station.

2 is a power amplifier diagram of a digital TRS base station according to an embodiment of the present invention;

3 is a detailed configuration diagram of the Doherty amplifier of FIG.

*** Explanation of Main References ***

110: first signal splitter 121, 122, 123: second signal splitter

130: Doherty amplifier 131-136: Doherty amplifier

141-143: first signal combiner 150: second signal combiner

201: Doherty Signal Splitter 210: Input Matching Unit

220: amplification unit 230: output matching unit

240: phase compensation unit 250: lambda / 4 delay line

260: impedance conversion circuit 261, 262: chip capacitor

263: wire-wound inductor

Claims (5)

A first signal distributor for distributing an input RF signal RFin; A second signal splitter for distributing an input RF signal RFin distributed by the first signal splitter into an RF1 signal that is a reference signal and an RF2 signal that is a 90 ° phase difference signal of the RF1 signal; A first Doherty amplifier for power amplifying the distributed RF1 signal by a carrier amplifier and a picking amplifier and outputting the amplified signal RF1A, and a signal amplified by power amplifying the distributed RF2 signal by a carrier amplifier and a peaking amplifier A Doherty amplifier having a second Doherty amplifier for outputting (RF2A) configured in parallel; A first signal combiner for coupling the signal RF1A amplified by the first Doherty amplifier and the signal RF2A amplified by the second Doherty amplifier into a signal RFout in phase; And And a second signal combiner configured to output a signal RFout coupled in phase by the first signal combiner. The method according to claim 1, wherein the first and second Doherty amplifier, A Doherty signal splitter that receives the RF1 signal or the RF2 signal distributed by the second signal splitter and distributes the RF11 signal or RF21 signal as a reference signal and an RF12 signal or RF22 signal that is a 90 ° phase difference signal between the RF11 signal or the RF21 signal Wow, 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 configured, 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 composed of a picking amplifier to output; 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 compensating for the phase of the output matched signal RF11A or RF21A, and a second transmission line compensating for the phase of the output matched signal RF12A or RF22A; 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; To convert the output impedance of the signal (RF1A or RF2A) in which the phase compensated signal (RF12A or RF22A) and the signal (RF11A or RF21A) delayed by the λ / 4 delay line are in phase to 50 ohm characteristic impedance And an impedance conversion circuit including two chip capacitors connected in parallel and a wound inductor connected in series between the two chip capacitors. A first signal splitter configured to distribute the input RF signal RFin to a plurality of paths; A plurality of second signal splitters for distributing each of the plurality of input RF signals RFin distributed by the first signal splitter into an RF1 signal as a reference signal and an RF2 signal as a 90 degree phase difference signal of the RF1 signal; A first Doherty amplifier for outputting the amplified signal RF1A by power amplifying each RF1 signal distributed by the plurality of second signal splitters by a carrier amplifier and a picking amplifier, and by the plurality of second signal splitters A plurality of Doherty amplifiers each including a plurality of Doherty amplifiers configured to have a second Doherty amplifier configured to perform power amplification on each of the divided RF2 signals by the carrier amplifier and the picking amplifier and output the amplified signal RF2A; A plurality of first signal combiners for coupling the first signal RF4 and the second signal RF5 amplified by the first Doherty amplifier and the second Doherty amplifier, respectively, connected to each of the plurality of Doherty amplifiers; And And a second signal combiner configured to combine and output a signal coupled by each of the plurality of first signal combiners into an RF output signal (RFout). The method of claim 3, wherein the first Doherty amplifier and the second Doherty amplifier, A Doherty signal that receives the RF1 signal or the RF2 signal distributed by the second signal splitter 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 the RF21 signal. With dispenser, 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 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 composed of a picking amplifier to output; 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 compensating for the phase of the output matched signal RF11A or RF21A, and a second transmission line compensating for the phase of the output matched signal RF12A or RF22A; 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; To convert the output impedance of the signal (RF1A or RF2A) in which the phase compensated signal (RF12A or RF22A) and the signal (RF11A or RF21A) delayed by the λ / 4 delay line are in phase to 50 ohm characteristic impedance And an impedance conversion circuit including two chip capacitors connected in parallel and a winding type inductor connected in series between the two chip capacitors. The power amplifier of claim 1 or 3, wherein the input RF signal is a four-channel RF signal.

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