JP2015531555A - Remote radio equipment - Google Patents

Abstract

A remote radio apparatus applied to a radio communication system is provided. The remote radio device includes a detection interface, and a signal of the antenna feeding interface is coupled to the detection interface by a coupler. In the detection, it is directly determined whether or not a failure has occurred in the remote wireless device due to detection of the detection interface, the detection is even easier, there is no need to disconnect the antenna feeding cable during operation of the device, and an attenuator is added separately There is no need to add a remote wireless device, and it is not necessary to disassemble the remote wireless device.

Description

  The present invention relates to wireless communication systems, and specifically to remote wireless units.

  Usually, an RRU (Remote Radio Unit / Remote Radio Unit) is applied to an outdoor tower or rooftop (for example, a base station), and has a high mounting height and is inconvenient to carry. The RRU usually includes a case, an antenna power supply interface provided in the case and connected to the antenna power supply cable, a power supply plate and a transmission / reception plate provided in the case, and a duplexer connected to each interface. . If a problem occurs during the actual operation of the RRU, it is determined that a failure has occurred in the RRU. When attempting to check, disconnect the antenna power cable and connect an attenuator from the outside of the case to the antenna power interface. The signal output from the RRU ANT (antenna feeding port) is measured from the RRU, or the RRU is disassembled and measured. Such an operation is complicated and dangerous, and only the output power in the forward direction of the interface can be detected.

  The present invention is easy to detect in view of the problem that the operation is complicated when detecting the failure of the RRU, the risk is high, and only the output power in the forward direction of the interface can be detected. At least one of the above problems is detected. It is an object of the present invention to provide a remote wireless device that can solve the problem.

  In order to solve the above technical problem, the present invention includes at least one antenna feeding interface for connecting an antenna feeding cable, and further includes at least one combination of a detection interface and a coupler. , A detection interface and a coupler are provided, and the coupler is connected to a signal transmission link from the antenna feeding interface, and provides a remote wireless device in which the detection interface and the coupler are connected in one of the combinations To do.

  The coupler includes an input end, a direct end, and a coupling end, and the coupler is connected to a signal transmission link from the antenna feeding interface via the input end and the direct end, and the coupling end is Connected to the detection interface.

  Corresponding to one antenna feeding interface, two of the combinations are provided, and the two couplers are connected in series to a signal transmission link from the antenna feeding interface, and an input terminal or a direct connection is provided between the two couplers. Connected through the end.

  The remote wireless device is provided with two antenna feeding interfaces.

  The remote wireless device includes a case, and the detection interface is provided in the case.

  The remote radio apparatus includes a duplexer connected to the antenna feeding interface, and the coupler is connected between the duplexer and the antenna feeding interface.

  The remote radio apparatus includes a duplexer connected to the antenna feeding interface, and the coupler is fixed to the duplexer.

  In one embodiment, the case is further provided with a groove, and the detection interface is provided in the groove.

  A cover plate is further provided at the opening of the groove.

  In another embodiment, the remote radio apparatus includes a case, a hole and a cover plate for covering the hole are provided in the case, and the detection interface is provided in the hole.

  In use, mark the actual coupling degree of the corresponding detection interface. In detection, if the signal of the detection interface is directly measured with a spectrum analyzer and the degree of coupling is added to it, the forward power or reverse power of the antenna feeding interface can be obtained and output from the antenna feeding interface. The signal spectrum can be investigated or demodulated to investigate the signal quality.

  According to the present invention, the following effects can be realized. According to the present invention, a remote radio device is provided, a detection interface is provided, and a signal is transmitted from an antenna feeding interface to a detection interface by a coupler, whereby a failure occurs in the remote radio device due to detection of the detection interface. It is easier to detect whether or not it has been done, it is easier to detect, there is no need to disconnect the antenna feeding cable during the operation of the equipment (ie, there is no need to interrupt the service work), and an additional attenuator is added There is no need to disassemble the remote wireless device, and maintenance difficulty and workload can be reduced.

FIG. 1 is a schematic view of a transmission structure according to an embodiment of the present invention. FIG. 2 is a schematic view of a partial cross-sectional structure from another direction of FIG.

Hereinafter, the present invention will be described in more detail with reference to specific embodiments and drawings.
Referring to FIGS. 1 and 2, according to one embodiment of the present invention, a remote wireless device is provided and includes at least one antenna feed interface for connecting an antenna feed cable (preferred embodiment is shown in FIG. 1). And 2, two antenna feeding interfaces are shown, a first ANT antenna feeding interface 2 and a second ANT antenna feeding interface 3), at least one detection interface (as a preferred embodiment, in FIGS. 1 and 2). Two pairs, ie, the first FWD detection interface 9, the first REV detection interface 10, the second FWD detection interface 7, and the second REV detection interface 8). The same number of couplers as the detection interface Further comprising a 1 and, the coupler 11 is connected to the signal transmission link from the antenna feed interface. The detection interface realizes detection of the antenna feeding interface by connecting the coupler 11 (adding an RF cable (high frequency cable 6) and connecting it can solve the problem of insufficient connection length). it can). By providing a detection interface and coupling the signal of the antenna feeding interface to the detection interface by the coupler 11, it is directly determined whether or not a failure has occurred in the remote wireless device due to detection of the detection interface. Furthermore, it is simpler, it is not necessary to cut off the antenna feeding cable during the operation of the device, there is no need to add an attenuator separately, there is no need to disassemble the remote radio device, and the maintenance difficulty and the amount of work can be reduced. .

  Specifically, the coupler 11 includes an input end, a direct end, and a coupling end, and the coupler 11 is connected to a signal transmission link from the antenna feeding interface via the input end and the direct end. The coupling end is connected to the detection interface.

  Specifically, the antenna power supply interface includes a transmission signal (forward power) and a reception signal (reverse power), and two couplers 11 are provided for one antenna power supply interface, and the two couplers 11 are the antennas. The two couplers 11 are connected to each other via an input end or a direct end, in series with a signal transmission link from the power supply interface. As described above, when two couplers 11 are directly connected in the reverse direction, a transmission signal is detected at the coupling end of one of the couplers 11 and detected at the coupling end of the other coupler 11. It is the received signal. If two couplers 11 are provided, more functions can be detected.

  In implementation, the remote radio device can also be provided with two antenna feeding interfaces, correspondingly provided with four detection interfaces and four couplers 11.

  In the case of providing more antenna feeding interfaces at the time of implementation, all parameters can be detected if a maximum of two detection interfaces and two couplers 11 are provided for each antenna feeding interface.

  Specifically, the remote radio apparatus includes a duplexer connected to the antenna power supply interface, and the coupler 11 is connected to a signal transmission link from the antenna power supply interface, and is connected between the duplexer and the antenna power supply interface. You can also. In the manufacturing method, one coupler 11 is mounted in series at the connection portion between the duplexer and the antenna feeding interface, and the coupling end of the coupler 11 is connected to the detection interface via the high-frequency cable 6. In addition, the coupler can be fixed to the duplexer using a screw during implementation.

  Specifically, the remote wireless device includes the case 1 and the detection interface is provided in the case, thereby making it possible to facilitate detection.

  In implementation, the case 1 can be further provided with a groove, and the detection interface can be provided in the groove. The role of protecting and covering the detection interface is realized. A cover plate can be further provided in the opening of the groove, and further protective action can be realized.

  In implementation, the detection interface can be provided in the hole by directly providing the case 1 with a hole and a cover plate covering the hole.

  At the time of implementation, the RRU power switch 5 may be provided in the case 1.

  In another embodiment, the remote wireless device may further include a spectrum analyzer having a power measurement mode and a demodulation mode, and the spectrum analyzer may further include an RF input port for connecting to the detection interface.

The embodiment shown in FIGS. 1 and 2 will be described in detail below.
As shown in the figure, the RRU is provided with two antenna feeding interfaces (that is, the first ANT antenna feeding interface 2 and the second ANT antenna feeding interface 3), and correspondingly, two pairs (four). Detection interfaces (that is, a first FWD detection interface 9, a first REV detection interface 10, a second FWD detection interface 7, and a second REV detection interface 8) are provided. Among them, the first FWD detection interface 9 detects the transmission signal of the first ANT antenna power supply interface 2, the first REV detection interface 10 detects the reception signal of the first ANT antenna power supply interface 2, and the second The FWD detection interface 7 detects the transmission signal of the second ANT antenna feeding interface 3, and the second REV detection interface 8 detects the reception signal of the second ANT antenna feeding interface 3.

  RRU first ANT antenna feeding interface 2 forward power coupler 11 (coupler in the first connection direction) and reverse power coupler 11 (connected in the opposite direction to the first connection direction) The output of the coupler) is connected to the first FWD detection interface 9 and the first REV detection interface 10 (both can use SMA connectors), and the actual coupling degree is marked. In actual application, the spectrum analyzer is directly used to detect the signals of the first FWD detection interface 9 and the first REV detection interface 10, and if the degree of coupling is added, the first ANT antenna feeding interface 2 The forward power and the reverse power can be obtained, the spectrum of the signal output from the first ANT antenna feeding interface 2 can be investigated or demodulated, and the signal quality can be investigated. Similarly, the outputs of the forward power coupler 11 and the reverse power coupler 11 of the second ANT antenna feeding interface 3 of the RRU are used to detect the second FWD detection interface 7 and the second REV detection in the operation maintenance window 4. Connect to interface 8 and mark the actual degree of coupling. In actual application, if the signals of the second FWD detection interface 7 and the second REV detection interface 8 are detected directly using a spectrum analyzer and the degree of coupling is added, the second ANT antenna feeding interface 3 The forward power and the reverse power can be obtained, the spectrum of the signal output from the second ANT antenna feeding interface 3 can be investigated or demodulated, and the signal quality can be investigated.

  In implementation, the detection interface can be provided in the upper half of the RRU case 1 (ie located on the power supply plate and the receiving and transmitting plate inside the RRU). Thereby, the convenience of wiring can be aimed at.

Specifically, the operations in the detection of the implementation shown in FIGS. 1 and 2 are as follows.
(1) Detection of the first FWD detection interface 9 The RF input port of the portable spectrum analyzer is connected to the first FWD detection interface 9, the spectrum analyzer is set to the power measurement mode, and the forward output power is measured. Thereafter, the actual forward output power of the first ANT antenna feeding interface 2 can be obtained by adding the degree of coupling corresponding to the first FWD detection interface 9 (which can be marked around the interface) (step). 1).
If the connection is made as in step 1 and the spectrum analyzer is set to the demodulation mode and the modulation quality of the forward output signal is detected, the modulation quality of the forward output signal of the first ANT antenna feeding interface 2 can be obtained (step 2).

(2) Detection of the first REV detection interface 10 The RF input port of the portable spectrum analyzer is connected to the first REV detection interface 10 in the operation maintenance window, the spectrum analyzer is set to the power measurement mode, and the reverse input power is set. , And then adding the degree of coupling corresponding to the first REV detection interface 10, the actual reverse input power of the first REV detection interface 10 is obtained. The VSWR (voltage standing wave ratio) of the first ANT antenna feeding interface 2 can be derived from the forward output power of Step 1 of the operation method (1) (Step 1).
By connecting as in step 1, the spectrum analyzer is set to the demodulation mode and the modulation quality of the signal is measured, and the modulation quality of the reverse input signal of the first ANT antenna feeding interface 2 is obtained (step 2).

(3) Detection of the second FWD detection interface 7 The RF input port of the portable spectrum analyzer is connected to the second FWD detection interface 7 in the operation maintenance window, the spectrum analyzer is set to the power measurement mode, and the forward output power is set. , And then adding the degree of coupling corresponding to the second FWD detection interface 7, the actual forward output power of the second ANT antenna feed interface 3 is obtained (step 1).
The connection is made as in step 1, the spectrum analyzer is set to the demodulation mode, the modulation quality of the forward output signal is measured, and the modulation quality of the forward output signal of the second ANT antenna feeding interface 3 is obtained (step 2). ).

(4) Detection of the second REV detection interface 8 The RF input port of the portable spectrum analyzer is connected to the second REV detection interface 8 in the operation maintenance window, the spectrum analyzer is set to the power measurement mode, and the reverse input power is set. , And then adding the degree of coupling corresponding to the second REV detection interface 8, the actual reverse input power of the second ANT antenna feed interface 3 is obtained. The VSWR of the second ANT antenna feeding interface 3 can be derived from the forward output power of Step 1 of the operation method (3) (Step 1).
The connection is made as in step 1 and the spectrum analyzer is set to the demodulation mode to measure the modulation quality of the signal, and the modulation quality of the reverse input signal of the second ANT antenna feeding interface 3 is obtained (step 2).

  Here, in the existing 2T2R (two transmissions, two receptions) RRU, the reception antenna and the transmission antenna are usually integrated, and the transmission pole and the reception pole are not distinguished. Usually, reception and transmission are performed using the same antenna. Although there is a special structure such as 2T4R (2 transmissions, 4 receptions), for example, it is merely a distinction on the RRU structure, and the same antennas are used. The present invention refers to 2T2R RRU. And based on the above-mentioned principle, it is also possible to apply to other RRU like 2T4R RRU, for example.

  The above is a detailed description of the present invention by combining specific embodiments, and the specific implementation of the present invention should not be recognized as being limited to these descriptions. A person skilled in the art can perform simple estimation or switching within a range not departing from the spirit of the present invention, and any of these should be considered as included in the protection scope of the present invention.

1 Case 2 First antenna feeding interface 3 Second antenna feeding interface 4 Operation maintenance window 5 Power switch 6 High-frequency cable 7 Second FWD detection interface 8 Second REV detection interface 9 First FWD detection interface 10 First REV detection interface 11 coupler

Claims (10)

At least one antenna feeding interface for connecting an antenna feeding cable is provided, and at least one combination of a detection interface and a coupler is provided, and each of the combinations includes one detection interface and one coupler. ,
The coupler is connected to a signal transmission link from the antenna feeding interface,
In one of the combinations, a remote wireless device to which a detection interface and a coupler are connected. The coupler includes an input end, a direct end, and a coupling end,
The remote radio device according to claim 1, wherein the coupler is connected to a signal transmission link from the antenna feeding interface via an input end and a direct end, and the coupling end is connected to the detection interface.   Corresponding to one antenna feeding interface, two of the combinations are provided, and the two couplers are connected in series to a signal transmission link from the antenna feeding interface, and an input terminal or a direct connection is provided between the two couplers. The remote radio apparatus according to claim 2, which is connected via an end.   The remote radio apparatus according to claim 3, wherein two antenna feeding interfaces are provided.   The remote wireless device according to claim 1, further comprising a case, wherein the detection interface is provided in the case.   The remote radio apparatus according to claim 5, wherein a groove is further provided in the case, and the detection interface is provided in the groove.   The remote radio apparatus according to claim 6, further comprising a cover plate at the opening of the groove.   The remote wireless device according to claim 1, further comprising a case, wherein the case is provided with a hole and a cover plate for covering the hole, and the detection interface is provided in the hole.   The remote radio apparatus according to claim 1, further comprising: a duplexer connected to the antenna feeding interface, wherein the coupler is connected between the duplexer and the antenna feeding interface.   The remote radio apparatus according to claim 9, further comprising the duplexer connected to the antenna feeding interface, wherein the coupler is fixed to the duplexer.

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