阅读说明：本技术 频分多流射频分布系统、信号传输方法 (Frequency division multi-stream radio frequency distribution system and signal transmission method ) 是由 顾伟 张宝阳 张林嘉 磨善鹏 王鹏 彭艳芳 刘会春 曾亚飞 任志勇 王广 彭艺祥 于 2021-07-07 设计创作，主要内容包括：本申请的实施例提供了一种频分多流射频分布系统、信号传输方法,该系统包括近端设备、远端设备和分布式天线子系统DAS：近端设备,用于将多种无线通信体制或空分多流的射频信号变频混合成混合射频信号,所述混合射频混合信号中每种无线通信体制或空分多流的射频信号所处的频段不同；远端设备,用于将所述混合射频信号恢复成所述多种无线通信体制或空分多流的射频信号；分布式天线子系统DAS,用于将所述混合射频信号由所述近端设备传输至所述远端设备,以及对所述混合射频信号进行分配。本申请能够实现了单通道DAS系统用于多体制、多流射频信号的室分。(The embodiment of the application provides a frequency division multiple stream radio frequency distribution system and a signal transmission method, wherein the system comprises near-end equipment, far-end equipment and a Distributed Antenna Subsystem (DAS): the near-end equipment is used for mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals in a frequency conversion mode, wherein the frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency signals are different; the remote equipment is used for restoring the mixed radio frequency signals into radio frequency signals of the multiple wireless communication systems or space division multiple streams; a distributed antenna subsystem DAS for transmitting the mixed radio frequency signal from the near-end device to the far-end device and distributing the mixed radio frequency signal. The application can realize that the single-channel DAS is used for the indoor division of multi-system and multi-stream radio frequency signals.)

1. A frequency division multi-stream radio frequency distribution system is characterized by comprising near-end equipment, far-end equipment and a Distributed Antenna Subsystem (DAS):

the near-end equipment is used for mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals in a frequency conversion mode, wherein the frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency signals are different;

the remote equipment is used for restoring the mixed radio frequency signals into radio frequency signals of the multiple wireless communication systems or space division multiple streams;

a Distributed Antenna Subsystem (DAS) for distributing the mixed radio frequency signal and transmitting the mixed radio frequency signal from the near-end device to the far-end device.

2. The system of claim 1,

the near-end equipment comprises a near-end frequency conversion module and a near-end combiner, the near-end frequency conversion module is used for carrying out frequency conversion on the radio frequency signals of multiple wireless communication systems or space division multiple streams, and the near-end combiner is used for mixing the radio frequency signals of the multiple wireless communication systems or space division multiple streams after frequency conversion into the mixed radio frequency signals;

the far-end device comprises a far-end frequency conversion module and a far-end combiner, the far-end combiner is used for restoring the mixed radio frequency signals into the radio frequency signals of the multiple wireless communication systems or the space division multiple streams after frequency conversion, and the far-end frequency conversion module is used for carrying out frequency conversion on the radio frequency signals of the multiple wireless communication systems or the space division multiple streams after frequency conversion to restore the radio frequency signals of the multiple wireless communication systems or the space division multiple streams.

3. The system of claim 2,

the near-end equipment further comprises a near-end feed module, wherein the near-end feed module is used for mixing the mixed radio-frequency signal and the direct-current power supply signal into a radio-frequency power supply mixed signal;

the remote device further comprises a remote feed module, wherein the remote feed module is used for restoring the radio frequency power supply mixed signal into the mixed radio frequency signal and the direct current power supply signal;

the distributed antenna subsystem DAS is further configured to transmit the radio frequency power supply mixed signal from the near-end device to the far-end device.

4. The system of claim 3, further comprising a DC power source for powering the remote frequency conversion module.

5. The system of claim 3, further comprising a broadband diversity antenna comprising one or more of a trunked communication antenna element, a 4G multi-stream antenna element, a 5G multi-stream antenna element, and a WiFi multi-stream antenna element.

6. The system of any one of claims 1 to 5, wherein the plurality of radio frequency signals comprises one or more of 2G radio frequency signals, 3G radio frequency signals, 4G radio frequency signals, 5G radio frequency signals, WiFi radio frequency signals, and trunked communication radio frequency signals.

7. A signal transmission method, comprising:

at a near-end device, frequency-converting and mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals, wherein the frequency bands of the radio frequency signals of each wireless communication system in the mixed radio frequency signals are different;

at the remote device, recovering the mixed radio frequency signal into radio frequency signals of the plurality of wireless communication systems or space division multiple streams;

and distributing the mixed radio frequency signal in a Distributed Antenna Subsystem (DAS), and transmitting the mixed radio frequency signal from the near-end equipment to the far-end equipment.

8. A signal transmission method, comprising:

at a near-end device, frequency-converting and mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals, and mixing the mixed radio frequency signals and direct current power signals into radio frequency power source mixed signals, wherein the frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency mixed signals are different;

at a remote device, restoring the radio frequency power supply mixed signal into the mixed radio frequency signal and the direct current power supply signal, and restoring the mixed radio frequency signal into radio frequency signals of the multiple wireless communication systems or space division multiple streams;

and distributing the radio frequency power supply mixed signal in a Distributed Antenna Subsystem (DAS), and transmitting the radio frequency power supply mixed signal from the near-end equipment to the far-end equipment.

Technical Field

Embodiments of the present application relate to the field of communications technologies, and in particular, to a frequency division multiple stream radio frequency distribution system and a signal transmission method.

Background

Because the MIMO technology relies on the space diversity and multiplexing of electromagnetic wave transmission, the DAS transmits electromagnetic wave signals in a single radio frequency cable, and spatial multipath channels are lost, the single-channel DAS with huge stock in China cannot realize multi-channel MIMO room division coverage and cannot be directly built into a room division system capable of realizing MIMO.

Disclosure of Invention

The embodiment of the application provides a frequency division multi-stream radio frequency distribution system and a signal transmission method, which can realize the indoor division of radio frequency signals of multiple wireless communication systems or air division multi-stream through a single-channel DAS system.

In a first aspect of the present application, a frequency division multiple stream radio frequency distribution system is provided, which includes a near-end device, a far-end device, and a distributed antenna subsystem DAS: the near-end equipment is used for mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals in a frequency conversion mode, wherein the frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency signals are different; the remote equipment is used for restoring the mixed radio frequency signals into radio frequency signals of the multiple wireless communication systems or space division multiple streams; a Distributed Antenna Subsystem (DAS) for distributing the plurality of mixed radio frequency signals and transmitting the mixed radio frequency signals from the near-end device to the far-end device.

In a possible implementation manner, the near-end device includes a near-end frequency conversion module and a near-end combiner, where the near-end frequency conversion module is configured to perform frequency conversion on the radio frequency signals of multiple wireless communication systems or space division multiple streams, and the near-end combiner is configured to mix the radio frequency signals of multiple wireless communication systems or space division multiple streams after the frequency conversion into the mixed radio frequency signal; the far-end device comprises a far-end frequency conversion module and a far-end combiner, the far-end combiner is used for restoring the mixed radio frequency signals into the radio frequency signals of the multiple wireless communication systems or the space division multiple streams after frequency conversion, and the far-end frequency conversion module is used for carrying out frequency conversion on the radio frequency signals of the multiple wireless communication systems or the space division multiple streams after frequency conversion to restore the radio frequency signals of the multiple wireless communication systems or the space division multiple streams.

In a possible implementation manner, the near-end device further includes a near-end feeding module, where the near-end feeding module is configured to mix the mixed radio frequency signal and the dc power signal into a radio frequency power mixed signal; the remote device further comprises a remote feed module, wherein the remote feed module is used for restoring the radio frequency power supply mixed signal into the mixed radio frequency signal and the direct current power supply signal; the distributed antenna subsystem DAS is further configured to transmit the radio frequency power supply mixed signal from the near-end device to the far-end device.

In a possible implementation manner, the remote frequency conversion module further includes a dc power supply, and the dc power supply is configured to supply power to the remote frequency conversion module.

In a possible implementation manner, the wireless communication system further includes a broadband diversity antenna, where the broadband diversity antenna includes one or more of a trunking communication antenna element, a 4G multi-stream antenna element, a 5G multi-stream antenna element, and a WiFi multi-stream antenna element.

In one possible implementation, the plurality of radio frequency signals include one or more of 2G radio frequency signals, 3G radio frequency signals, 4G radio frequency signals, 5G radio frequency signals, WiFi radio frequency signals, and trunked communication radio frequency signals.

In a second aspect of the present application, there is provided a signal transmission method including: at a near-end device, frequency-converting and mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals, wherein the frequency bands of the radio frequency signals of each wireless communication system in the mixed radio frequency signals are different; at the remote device, recovering the mixed radio frequency signal into radio frequency signals of the plurality of wireless communication systems or space division multiple streams; and distributing the mixed radio frequency signal in a Distributed Antenna Subsystem (DAS), and transmitting the mixed radio frequency signal from the near-end equipment to the far-end equipment.

In a third aspect of the present application, there is provided a signal transmission method including: at a near-end device, frequency-converting and mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into mixed radio frequency signals, and mixing the mixed radio frequency signals and direct current power signals into radio frequency power source mixed signals, wherein the frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency mixed signals are different; at a remote device, restoring the radio frequency power supply mixed signal into the mixed radio frequency signal and the direct current power supply signal, and restoring the mixed radio frequency signal into radio frequency signals of the multiple wireless communication systems or space division multiple streams; and distributing the radio frequency power supply mixed signal in a Distributed Antenna Subsystem (DAS), and transmitting the radio frequency power supply mixed signal from the near-end equipment to the far-end equipment.

In the frequency division multiple stream radio frequency distribution system and the signal transmission method provided in the embodiment of the present application, radio frequency signals of multiple wireless communication systems or air division multiple streams are subjected to frequency conversion mixing by a near-end device, the radio frequency signals are transmitted to a far-end device by a DAS system, and are restored to radio frequency signals of multiple wireless communication systems or air division multiple streams by the far-end device, and finally, the radio frequency signals of multiple wireless communication systems or air division multiple streams are distributed to corresponding antenna oscillators by the DAS system.

It should be understood that what is described in this summary section is not intended to limit key or critical features of the embodiments of the application, nor is it intended to limit the scope of the application. Other features of the present application will become apparent from the following description.

Drawings

The above and other features, advantages and aspects of various embodiments of the present application will become more apparent by referring to the following detailed description when taken in conjunction with the accompanying drawings.

Fig. 1 shows a block diagram of a frequency division multiple stream radio frequency distribution system according to an embodiment of the present application.

Fig. 2 shows a schematic diagram of a near-end device in a frequency division multiple stream radio frequency distribution system according to an embodiment of the present application.

Fig. 3 shows a schematic diagram of a remote device in a frequency division multiple stream radio frequency distribution system according to an embodiment of the present application.

Fig. 4 shows a block diagram of another frequency division multiple stream radio frequency distribution system according to an embodiment of the present application.

Fig. 5 shows a circuit diagram of a feed module in another frequency division multiple stream radio frequency distribution system according to an embodiment of the present application.

Fig. 6 shows a flow chart of a signal transmission method according to an embodiment of the application.

Fig. 7 shows a flow diagram of another signal transmission method according to an embodiment of the application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

In order to facilitate understanding of the embodiments of the present application, some terms referred to in the embodiments of the present application are first explained.

A Distributed Antenna subsystem (or DAS) is a communication rf signal distribution network formed by a plurality of spatially separated Antenna nodes connected to various directional couplers or power splitters through rf coaxial cable transmission media in a predetermined space or building.

MIMO technology is intended to improve the capacity and spectrum utilization of a communication system by a multiple without increasing the frequency occupation. It can be defined that there are many independent space channels between the sending end and the receiving end, which improves the link performance of the signal and increases the data throughput.

At present, in order to solve the problem of wireless communication in a closed space (an underground garage, an indoor space, an inside of a cabin, an underground tunnel and the like), people build a large number of DAS systems, the DAS systems are based on radio frequency transmission of feed cables, mainly comprise signal sources, relay equipment, a combiner, a power divider, a coupler, a coaxial cable, an antenna and the like, and are used for cluster communication, Wi-Fi signal coverage and 2/3/4G mobile communication systems.

With the development of wireless communication technology, communication bandwidth and capacity are rapidly increased, technologies such as 5G and Wi-Fi6 are widely put into commercial use, the MIMO technology is one of core technologies of broadband wireless communication, and the MIMO technology refers to that a plurality of transmitting antennas and receiving antennas are respectively used at a transmitting end and a receiving end, so that signals are transmitted and received through the plurality of antennas at the transmitting end and the receiving end, thereby improving communication quality and performance. The multi-antenna multi-transmission multi-reception mobile communication system can fully utilize space resources, realizes multi-transmission and multi-reception through a plurality of antennas, can improve the system channel capacity by times under the condition of not increasing frequency spectrum resources and antenna transmitting power, and is regarded as the core technology of next generation mobile communication. The essence of the MIMO technology is to provide a spatial diversity gain and a spatial multiplexing gain for the system, the former ensures the transmission reliability of the system, and the latter improves the transmission rate of the system.

Because the MIMO technology relies on the space diversity and multiplexing of electromagnetic wave transmission, the DAS transmits electromagnetic wave signals in a single radio frequency cable, and spatial multipath channels are lost, the single-channel DAS with huge stock in China cannot realize multi-channel MIMO room division coverage and cannot be directly built into a room division system capable of realizing MIMO. Furthermore, the transmission loss of electromagnetic waves with different frequencies in a radio frequency cable is different, the higher the frequency is, the larger the loss is, most existing DAS systems are designed and constructed for 2/3/4G mobile communication, and it is difficult to meet the requirements of radio frequency distribution in 5G and WiFi5.8GHz frequency bands with higher communication frequencies.

Therefore, the embodiment of the present application provides a frequency division multiple stream radio frequency distribution system. Referring to fig. 1, the system includes a proximal device 100, a distal device 200, and a DAS system 300.

The near-end device 100 is configured to frequency-convert and mix radio frequency signals of multiple wireless communication systems or space division multiple streams into a mixed radio frequency signal, where frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency signal are different.

Specifically, the near-end device 100 includes a near-end frequency conversion module and a near-end combiner, where the near-end frequency conversion module is configured to perform frequency conversion on radio frequency signals of multiple wireless communication systems or space division multiple streams to implement co-cable transmission and reduce transmission loss, and the near-end combiner is configured to mix the radio frequency signals of the multiple wireless communication systems or space division multiple streams after the frequency conversion into a mixed radio frequency signal.

In the embodiment of the present application, the radio frequency signals of the multiple wireless communication systems include, but are not limited to, 2G radio frequency signals, 3G radio frequency signals, 4G radio frequency signals, 5G radio frequency signals, WiFi radio frequency signals, and trunking communication radio frequency signals.

The principle of the near-end device 100 is described below by taking the near-end device 100 as an example to connect the trunking communication base station, the 4G base station, the 5G base station, the WiFi base station, and the WiFi6 base station.

Referring to fig. 2, the near-end device 100 includes a combiner and a plurality of frequency converters.

The trunking communication base station outputs a radio frequency stream signal which is directly connected to the combiner. The 5G base station outputs four radio frequency flow signals, each radio frequency flow signal is connected with a frequency converter, and each frequency converter is connected to the combiner. The WiFi base station outputs four radio frequency flow signals, each radio frequency flow signal is connected with a frequency converter, and each frequency converter is connected to the combiner. The 4G base station outputs a radio frequency flow signal which is directly connected to the combiner.

Certainly, when the 5G base station outputs two rf stream signals, each rf stream signal is connected to one frequency converter, and each frequency converter is connected to the combiner. When the WiFi base station outputs two radio frequency flow signals, each radio frequency flow signal is connected with one frequency converter, and each frequency converter is connected to the combiner.

Therefore, radio frequency flow signals of different wireless communication systems or space division multiple flows sent by different base stations are subjected to frequency conversion through the frequency converter, then are mixed through the combiner to form a path of mixed radio frequency signal, and the radio frequency signals of the different wireless communication systems or the space division multiple flows are in different frequency bands, so that shared transmission is realized.

The remote device 200 is configured to recover the mixed rf signal into rf signals of multiple wireless communication systems or spatial division multiple streams.

Specifically, the remote device 200 includes a remote frequency conversion module and a remote combiner, where the remote combiner is configured to restore the mixed radio frequency signal to a plurality of radio communication systems or space division multiple radio frequency signals after frequency conversion, and the remote frequency conversion module is configured to perform frequency conversion on the plurality of radio communication systems or space division multiple radio frequency signals after frequency conversion to restore the plurality of radio communication systems or space division multiple radio frequency signals to a plurality of radio communication systems or space division multiple radio frequency signals.

The frequency division multi-stream radio frequency distribution system further comprises a broadband diversity antenna, wherein the broadband diversity antenna comprises but is not limited to a trunking communication antenna element, a 4G multi-stream antenna element, a 5G multi-stream antenna element, a WiFi multi-stream antenna element and a WiFi6 multi-stream antenna element. Illustratively, the wide-band diversity antenna may be externally connected to the remote device 200. Illustratively, the wide-band diversity antenna may also be integral with the remote device 200.

The principle of the remote device 200 will be described below by taking the remote device 200 as an example to connect the cluster communication antenna element, the 4G multi-stream antenna element, the 5G multi-stream antenna element, the WiFi multi-stream antenna element, and the WiFi6 multi-stream antenna element.

Referring to fig. 3, the remote device 200 includes a combiner and a plurality of frequency converters. The far-end combiner restores the mixed radio-frequency signals into frequency-converted radio-frequency signals of multiple wireless communication systems or space division multiple streams, wherein the radio-frequency signals of the multiple wireless communication systems or space division multiple streams comprise trunking communication radio-frequency signals, 4G radio-frequency signals, 5G radio-frequency signals, WiFi radio-frequency signals and WiFi6 radio-frequency signals.

The trunked communication radio frequency signal is directly connected to the trunked communication antenna element.

The 4G radio frequency signal is connected to the 4G multi-stream antenna element.

Two or more null current signals of the 5G radio frequency signal are connected to the 5G multi-stream antenna element.

Two or more empty stream signals of the WiFi radio-frequency signal are connected to the WiFi multi-stream antenna element.

Therefore, the hybrid radio frequency signals are restored into radio frequency signals of various wireless communication systems or space division multiple streams after frequency conversion through the combiner, and then the radio frequency signals of various wireless communication systems or space division multiple streams after frequency conversion are restored into original frequencies and space division multiple streams through the frequency converter and transmitted to the antenna oscillator.

The DAS system 300 is used to transmit the mixed rf signal from the near-end device to the far-end device and distribute the mixed rf signal.

According to the embodiment of the application, radio frequency signals of multiple wireless communication systems or space division multiple streams are subjected to frequency conversion mixing through the near-end equipment 100, transmitted to the far-end equipment 200 by the DAS system 300, and restored to radio frequency signals of multiple wireless communication systems or space division multiple streams through the far-end equipment 200, and finally distributed to corresponding antenna oscillators by the DAS system 300.

It should be noted that, transmission losses of electromagnetic waves with different frequencies in a radio frequency cable are different, and the higher the frequency is, the larger the loss is, most existing DAS indoor subsystems are designed and constructed for 2/3/4G mobile communication, and are mostly used in a frequency band below 2.7GHz, and since 5G communication and Wi-Fi 5.8G communication use a communication frequency band above 3GHz, the DAS system cannot meet the requirement of radio frequency distribution. Therefore, the frequency of the radio frequency signals of various wireless communication systems can be reduced through the frequency converter to reduce the transmission loss, and only the frequency ranges of the radio frequency signals of each communication system are required to be ensured not to be overlapped and a certain frequency interval is required to be kept.

Illustratively, the frequency range of the cluster communication radio frequency signals is 0.8-0.9 GHz, the frequency range of 5G multi-stream radio frequency signals after being converted by the frequency converter is 0.9-1.2 GHz, the frequency range of wifi5.8ghz band multi-stream radio frequency signals after being converted by the frequency converter is 1.3-1.6 GHz, the frequency range of one null stream in the wifi2.4ghz band multi-stream radio frequency signals after being converted by the frequency converter is 1.7-1.8 GHz, and the original frequency bands are used by the other null stream (2.4GHz band) in the wifi2.4ghz band multi-stream radio frequency signals and the 4G radio frequency signals (1.8-2.7 GHz band).

In order to solve the indoor coverage problem of 5G signals, a novel optical fiber indoor distribution system is developed, and the system has the advantages of supporting MIMO technology, long transmission distance and 5G-NR upgrading, but has the problems of power supply reliability of remote equipment and secondary wiring construction of optical fibers and power lines because the remote equipment needs to adopt local nearby power supply.

Therefore, the embodiment of the present application further provides another frequency division multiple stream radio frequency distribution system. Referring to fig. 4, the system is different from the system shown in fig. 1 in that the near-end device 100 includes a near-end feeding module, and the far-end device 200 includes a far-end feeding module, and the same parts are not described again.

In this embodiment, the near-end feeding module is configured to mix the mixed rf signal and the dc power signal into an rf power mixed signal. The far-end feed module is used for restoring the radio frequency power supply mixed signal into a mixed radio frequency signal and a direct current power supply signal. The DAS system 300 is used to transmit the rf power mix signal from the near-end device 100 to the far-end device 200. It should be noted that the principle of the near-end feeding module and the far-end feeding module is the same. The near-end feeding module is taken as an example for explanation.

Referring to fig. 5, the mixed rf signal is input from the RFIN terminal, the DC power is input from the DC12V +, and the mixed rf signal is output from the RFOUT terminal after mixing by the near-end feeding module.

The far-end feeding module is opposite to the near-end feeding module, the radio frequency power supply mixed signal is input from the RFOUT end and is restored into a mixed radio frequency signal and a direct current power supply signal through the far-end feeding module, the mixed radio frequency signal is output from the RFIN end, and the direct current power supply signal is output from the DC12V + end.

The frequency-division multi-stream radio frequency distribution system further comprises a direct current power supply, and the direct current power supply is used for supplying power to the frequency-division multi-stream radio frequency distribution system. Illustratively, a direct current power supply may be external to the near-end device 100. Illustratively, the dc power source may also be integral with the near-end device 100.

According to the embodiment of the application, the mixed radio frequency signal and the direct current power supply signal are mixed into the radio frequency power supply mixed signal through the near-end feed module, the radio frequency power supply mixed signal is transmitted to the far-end equipment through the DAS, and the radio frequency power supply mixed signal is restored into the mixed radio frequency signal and the direct current power supply signal through the far-end feed module, so that power can be provided for the far-end equipment, and the problems of secondary construction and power supply reliability of power supply for the far-end equipment are solved.

In another aspect, the present application provides a signal transmission method. Referring to fig. 6, the method includes the steps of:

step 610, at the near-end device, mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into a mixed radio frequency signal, where frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency signal are different.

In step 620, at the remote device, the mixed rf signal is restored to rf signals of multiple wireless communication systems or space division multiple streams.

Step 630, in the DAS system, the mixed rf signal is transmitted from the near-end device to the far-end device, and the mixed rf signal is distributed.

In another aspect, the present application provides another method of signal transmission. Referring to fig. 7, the method includes the steps of:

step 710, at the near-end device, mixing radio frequency signals of multiple wireless communication systems or space division multiple streams into a mixed radio frequency signal, and mixing the mixed radio frequency signal and a direct current power supply signal into a radio frequency power supply mixed signal, where frequency bands of the radio frequency signals of each wireless communication system or space division multiple streams in the mixed radio frequency mixed signal are different.

And 720, at the remote equipment, restoring the radio frequency power supply mixed signal into a mixed radio frequency signal and a direct current power supply signal, and restoring the mixed radio frequency signal into radio frequency signals of multiple wireless communication systems or space division multiple streams.

Step 730, in the DAS system, the rf power mix signal is transmitted from the near-end device to the far-end device, and is distributed.

It can be clearly understood by those skilled in the art that, for convenience and brevity of description, the specific working process of the described method may refer to the corresponding process in the foregoing system embodiment, and is not described herein again.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be appreciated by those skilled in the art that the scope of the application referred to in the present application is not limited to the embodiments with a particular combination of the above-mentioned features, but also encompasses other embodiments with any combination of the above-mentioned features or their equivalents without departing from the spirit of the application. For example, the above features may be replaced with (but not limited to) features having similar functions as those described in this application.