CN117156422A - Aggregation communication system, device and storage medium - Google Patents

Abstract

The application discloses an aggregation communication system, equipment and a storage medium, relates to the technical field of communication, and is used for improving the efficiency of emergency communication. The aggregate communication system includes: the device comprises a first communication module, a second communication module, a routing switch and an aggregation control unit; the first communication module is used for receiving a network access signal sent by the terminal equipment in the emergency disposal site and sending the network access signal to the second communication module; the second communication module is used for receiving the network access signal sent by the first communication module so as to access the terminal equipment into the target core network based on the network access signal; the routing switch is used for providing network routing switching service for the first communication module, the second communication module and the aggregation control unit; the aggregation control unit is used for controlling protocol conversion and data exchange between the first communication module and the second communication module. The method and the device are applied to the scene of emergency communication.

Description

Aggregation communication system, device and storage medium

Technical Field

The present application relates to the field of communications technologies, and in particular, to an aggregate communications system, an apparatus, and a storage medium.

Background

At present, in various emergency rescue sites, communication equipment such as a public network base station, a digital cluster base station, a broadband ad hoc network base station, a WI-FI 6 dual-frequency access station, an Internet of things base station and the like is generally required to be deployed, and various business equipment such as a three-layer network routing switch, a high-throughput satellite access module, a comprehensive power supply module, a comprehensive spectrum sensing module, a weather sensing module, a ball control, a megaphone, an illuminating lamp and the like are required to be additionally arranged outside the emergency rescue sites so as to carry out emergency communication and command scheduling.

The devices are generally incompatible, relatively independent, can not be communicated and aggregated, have single functions and huge volumes, are complex in connection, seriously interfere with each other, are difficult to debug and networking, and can not rapidly conduct emergency communication and comprehensive service guarantee. Therefore, the efficiency of performing emergency communication is poor.

Disclosure of Invention

The application provides an aggregation communication system, equipment and a storage medium, which are used for solving the problems that various communication equipment and various service equipment in various emergency rescue sites are incompatible, relatively independent, can not be communicated and aggregated, and the equipment is numerous and miscellaneous and can not be used for rapidly carrying out emergency communication and comprehensive service guarantee, so that the efficiency of the emergency communication is improved.

In order to achieve the above purpose, the application adopts the following technical scheme:

in a first aspect, an aggregate communication system is provided, the aggregate communication system comprising: the device comprises a first communication module, a second communication module, a routing switch and an aggregation control unit; the first communication module is used for receiving a network access signal sent by the terminal equipment in the emergency disposal site and sending the network access signal to the second communication module; the second communication module is used for receiving the network access signal sent by the first communication module so as to access the terminal equipment into the target core network based on the network access signal; the routing switch is used for providing network routing switching service for the first communication module, the second communication module and the aggregation control unit; the aggregation control unit is used for controlling protocol conversion and data exchange between the first communication module and the second communication module.

In one possible implementation, the aggregate communication system further includes: a data acquisition terminal; the data acquisition terminal is used for acquiring target data in an emergency treatment site, and sending the target data to the rear end command scheduling platform through the first communication module and the second communication module, wherein the target data comprises at least one of the following: weather-aware data, visual-aware data; the back-end command scheduling platform is used for analyzing and processing the target data to obtain an analysis result and displaying the analysis result to staff; the route exchanger is also used for providing network route exchange service for the data acquisition terminal; the aggregation control unit is also used for controlling protocol conversion and data exchange among the data acquisition terminal, the first communication module and the second communication module.

In one possible implementation manner, the first communication module comprises a Long Term Evolution (LTE) public and private base station, a narrowband digital trunked base station and an internet of things base station, and the second communication module comprises a broadband ad hoc network base station, a full network access aggregation access module and a high-throughput satellite access module; the LTE public-private dual-purpose base station and the narrow-band digital trunking base station are used for receiving network access signals sent by the terminal equipment and sending the network access signals to any object in the broadband ad hoc network base station, the all-network access aggregation access module or the high-throughput satellite access module; the internet of things base station is used for receiving target data sent by the data acquisition terminal and sending the target data to any object in the broadband ad hoc network base station, the full-network access aggregation module or the high-flux satellite access module.

In one possible implementation, the aggregate communication system further includes: a sixth generation wireless network technology WI-FI 6 dual-frequency access station, a comprehensive spectrum sensing module and an antenna filtering trap; the WI-FI 6 dual-frequency access station is used for receiving a network access signal sent by the terminal equipment so as to provide a WI-FI signal for the terminal equipment based on the network access signal; the comprehensive spectrum sensing module is used for collecting radio spectrum data generated by the first communication module and radio spectrum data generated by the second communication module and sending the radio spectrum data generated by the first communication module and the radio spectrum data generated by the second communication module to the antenna filtering trap; the antenna filter trap is used for carrying out filtering processing and notch processing on the first communication module and the second communication module based on radio spectrum data generated by the first communication module and radio spectrum data generated by the second communication module.

In one possible implementation, the integrated spectrum sensing module is further configured to send the radio spectrum data generated by the first communication module and the radio spectrum data generated by the second communication module to the aggregation control unit; the aggregation control unit is used for analyzing and calculating the radio spectrum data generated by the first communication module and the radio spectrum data generated by the second communication module to obtain a radio carrier calculation result, and sending the radio carrier calculation result to the antenna filtering trap; the antenna filter trap is also used for carrying out antenna fundamental wave processing and antenna harmonic wave processing on the first communication module and the second communication module based on the radio carrier wave calculation result.

In one possible implementation, the aggregate communication system further includes: a shouting module and a lighting module; the shouting module is used for receiving the shouting instruction sent by the back-end command scheduling platform through the first communication module and the second communication module and shouting based on the shouting instruction; the illumination module is used for receiving illumination instructions sent by the back-end command scheduling platform through the first communication module and the second communication module and illuminating based on the illumination instructions.

In one possible implementation, the aggregate communication system further includes: a comprehensive power module and a heat dissipation management module; the integrated power module is used for supplying power to the first communication module, the second communication module, the routing switch, the aggregation control unit and the data acquisition terminal; the heat dissipation management module is used for dissipating heat for the first communication module, the second communication module, the routing switch, the aggregation control unit and the data acquisition terminal.

In one possible implementation, the aggregate communication system further includes: a wireless remote control unit; the wireless remote control unit is used for determining target equipment from the broadband ad hoc network base station, the full-network access aggregation module or the high-throughput satellite access module, so as to receive network access signals sent by the LTE public and private base station and the narrowband digital trunking base station and receive target data sent by the Internet of things base station based on the target equipment, wherein the target equipment is any object of the broadband ad hoc network base station, the full-network access aggregation module or the high-throughput satellite access module.

In a second aspect, an electronic device includes: a processor and a memory; wherein the memory is configured to store one or more programs, the one or more programs comprising computer-executable instructions that, when executed by the electronic device, cause the electronic device to perform a method corresponding to an aggregated communication system as in the first aspect.

In a third aspect, there is provided a computer readable storage medium storing one or more programs, the one or more programs comprising instructions, which when executed by a computer, cause the computer to perform a method as in the first aspect for an aggregated communication system.

The application provides an aggregation communication system, aggregation communication equipment and a storage medium, which are applied to various emergency rescue scenes. The aggregation communication system comprises a first communication module, a second communication module, a routing switch and an aggregation control unit, namely, the aggregation communication system can aggregate various devices, so that the problem of huge size of the devices is avoided. When emergency communication is carried out, a network access signal sent by a terminal device in an emergency disposal site can be received through the first communication module, and the network access signal is sent to the second communication module, so that the terminal device is accessed to a target core network through the second communication module. In the process, network route switching service can be provided through the route switch, protocol conversion and data exchange among the communication modules can be controlled through the aggregation control unit, namely normal communication among the terminal equipment, the first communication module, the second communication module and the target core network can be ensured through the route switch and the aggregation control unit, so that the problems that the emergency communication cannot be quickly carried out due to relative independence, incapability of intercommunication and incapability of aggregation among all the equipment are avoided, and the efficiency of the emergency communication is improved.

Drawings

Fig. 1 is a schematic structural diagram of an aggregation communication system according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the accompanying drawings in the embodiments of the present application.

In the description of the present application, "/" means "or" unless otherwise indicated, for example, A/B may mean A or B. "and/or" herein is merely an association relationship describing an association object, and means that three relationships may exist, for example, a and/or B may mean: a exists alone, A and B exist together, and B exists alone. Further, "at least one", "a plurality" means two or more. The terms "first," "second," and the like do not limit the number and order of execution, and the terms "first," "second," and the like do not necessarily differ.

At present, in the fields of emergency communication and command scheduling, each communication system is relatively independent, can not communicate with each other and has a single function. In various emergency rescue sites, communication and situation sensing equipment such as public network base stations, digital cluster base stations, broadband ad hoc network base stations, WI-FI 6 dual-frequency access stations, internet of things base stations and the like are often required to be deployed, and various equipment such as three layers of network routing switches, high-flux satellite access modules, comprehensive power modules, frequency spectrum sensing modules, weather sensing modules, distribution control balls, shouting lighting assemblies and the like are required to be additionally arranged outside the emergency rescue sites so as to carry out emergency communication and command scheduling.

However, the devices are incompatible and not aggregated, the total weight is up to 100kg, the devices are numerous and complicated, the devices are complicated in connection, the mutual interference is serious, the debugging and networking are difficult, and the emergency communication and the comprehensive service guarantee cannot be rapidly performed.

The application provides an aggregation communication system which comprises a first communication module, a second communication module, a routing switch and an aggregation control unit, namely the aggregation communication system can aggregate various devices, so that the problem of huge size of the devices is avoided. When emergency communication is carried out, a network access signal sent by a terminal device in an emergency disposal site can be received through the first communication module, and the network access signal is sent to the second communication module, so that the terminal device is accessed to a target core network through the second communication module. In the process, network route switching service can be provided through the route switch, protocol conversion and data exchange among the communication modules can be controlled through the aggregation control unit, namely normal communication among the terminal equipment, the first communication module, the second communication module and the target core network can be ensured through the route switch and the aggregation control unit, so that the problems that the emergency communication cannot be quickly carried out due to relative independence, incapability of intercommunication and incapability of aggregation among all the equipment are avoided, and the efficiency of the emergency communication is improved.

The embodiment of the application provides an aggregation communication system. Fig. 1 shows a schematic structure of an aggregated communication system. As shown in fig. 1, an aggregate communication system 10 includes: the wireless remote control system comprises an antenna filtering trap 11, a first communication module 12, a second communication module 13, a WI-FI 6 dual-frequency access station 14, a routing switch 15, an aggregation control unit 16, a data acquisition terminal 17, a comprehensive spectrum sensing module 18, a shouting module 19, a lighting module 20, a comprehensive power supply module 21, a heat dissipation management module 22 and a wireless remote control unit 23. The first communication module 12 specifically includes: an LTE public and private dual-purpose base station 121, a narrowband digital trunking base station 122, and an internet of things base station 123; the second communication module 13 specifically includes: a broadband ad hoc network base station 131, a full network access aggregation access module 132 and a high-throughput satellite access module 133; the data acquisition terminal 17 specifically includes: a weather awareness module 171 and a 360 degree vision sensor 172.

The antenna filtering trap 11 is configured to perform filtering, notch, antenna fundamental wave processing and antenna harmonic wave processing on the LTE public/private dual-purpose base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133 and the WI-FI 6 dual-frequency access station 14; the LTE-public/private base station 121 and the narrowband digital trunking base station 122 are configured to receive a network access signal sent by a terminal device in an emergency disposal site, and send the network access signal to any one of the broadband ad hoc network base station 131, the all-network access aggregation module 132, or the high-throughput satellite access module 133.

The internet of things base station 123 is configured to receive target data collected by the weather sensing module 171 and the 360-degree vision sensor 172, and send the target data to any object of the broadband ad hoc network base station 131, the all-network access aggregation module 132, or the high-throughput satellite access module 133; the broadband ad hoc network base station 131, the full network access aggregation access module 132 or the high throughput satellite access module 133 is configured to receive network access signals sent by the LTE public/private dual-purpose base station 121 and the narrowband digital trunking base station 122 and target data sent by the internet of things base station 123, so as to access the terminal device to the target core network based on the network access signals and send the target data to the back-end command scheduling platform; WI-FI 6 dual-frequency access station 14 is configured to receive a network access signal transmitted by a terminal device to provide a WI-FI signal to the terminal device based on the network access signal.

The routing switch 15 is configured to provide a quasi-three-layer network routing switching service for the LTE public/private dual-purpose base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133, and the WI-FI 6 dual-frequency access station 14; the aggregation control unit 16 is configured to control protocol conversion and data exchange among the LTE public/private base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133, the WI-FI 6 dual-frequency access station 14, the integrated spectrum sensing module 18, the weather sensing module 171, and the 360-degree vision sensor 172.

The comprehensive spectrum sensing module 18 is configured to collect radio spectrum data generated by the LTE public/private dual-purpose base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133, and the WI-FI 6 dual-frequency access station 14, and send the radio spectrum data to the antenna filtering trap 11 and the aggregation control unit 16; the shouting module 19 is used for carrying out shouting service on the periphery; the lighting module 20 is used for lighting services to the surroundings.

The integrated power module 21 is configured to supply power to the antenna filtering trap 11, the LTE public/private dual-purpose base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133, the WI-FI 6 dual-frequency access station 14, the routing switch 15, the aggregation control unit 16, the integrated spectrum sensing module 18, the shouting module 19, the lighting module 20, the heat dissipation management module 22, the wireless remote control unit 23, the weather sensing module 171, and the 360-degree vision sensor 172; the heat dissipation management module 22 is configured to dissipate heat for the antenna filtering trap 11, the LTE public/private dual-purpose base station 121, the narrowband digital trunked base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the all-network access aggregation module 132, the high-throughput satellite access module 133, the WI-FI 6 dual-frequency access station 14, the routing switch 15, the aggregation control unit 16, the integrated spectrum sensing module 18, the shouting module 19, the lighting module 20, the integrated power module 21, the wireless remote control unit 23, the weather sensing module 171, and the 360-degree vision sensor 172.

The wireless remote control unit 23 is used for performing manual and rapid control remote control switching among three links corresponding to the broadband ad hoc network base station 131, the all-network access aggregation access module 132 and the high-throughput satellite access module 133; the weather sensing module 171 is configured to collect weather sensing data and send the collected weather sensing data to the internet of things base station 123; the 360-degree vision sensor 172 is used for collecting vision sensing data and transmitting collected weather sensing data to the internet of things base station 123, so as to perform emergency communication and comprehensive service guarantee through the antenna filtering trap 11, the LTE public and private base station 121, the narrowband digital trunking base station 122, the internet of things base station 123, the broadband ad hoc network base station 131, the full-network access module 132, the high-throughput satellite access module 133, the WI-FI 6 dual-frequency access station 14, the routing switch 15, the aggregation control unit 16, the comprehensive spectrum sensing module 18, the shouting module 19, the lighting module 20, the comprehensive power module 21, the heat dissipation management module 22, the wireless remote control unit 23, the weather sensing module 171 and the 360-degree vision sensor 172.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 includes: a first communication module 12, a second communication module 13, a routing switch 15 and an aggregation control unit 16.

Specifically, the first communication module 12 is configured to receive a network access signal sent by a terminal device in an emergency treatment site, and send the network access signal to the second communication module 13; the second communication module 13 is configured to receive the network access signal sent by the first communication module 12, so as to access the terminal device to the target core network based on the network access signal; the routing switch 15 is configured to provide network routing switching services for the first communication module 12, the second communication module 13, and the aggregation control unit 16; the aggregation control unit 16 is used for controlling protocol conversion and data exchange between the first communication module 12 and the second communication module 13.

Optionally, according to actual situations and needs of the emergency rescue scene, a plurality of modes of communication base stations or communication modules (namely a first communication module and a WI-FI 6 dual-frequency access station) can be configured, wherein the first communication module comprises an LTE public and private base station, a narrowband digital trunking base station and an Internet of things base station, so that network access and communication services are provided for various terminal devices on the scene, and communication parameter setting, channel allocation, power control and other configurations can be performed on the first communication module and the WI-FI 6 dual-frequency access station according to actual needs. Meanwhile, the communication base station or the communication module can be tested and debugged to ensure the normal work of the communication base station or the communication module.

Three data return links (including a link for data return through a broadband ad hoc network base station, a link for data return through a full-network aggregation access module and a link for data return through a high-flux satellite access module) can be configured according to actual conditions and needs of an emergency rescue site so as to realize interconnection and intercommunication between various terminal devices on site, a target core network and a back-end command scheduling platform. The second communication module can be configured with communication parameter setting, channel allocation, power control and the like according to actual requirements, and is tested and debugged to ensure normal operation.

The three-layer network intelligent routing switch (i.e., routing switch) may be configured to provide network routing switching services for the first communication module, the second communication module, the WI-FI 6 dual-frequency access station, and the multimode intelligent aggregation control unit (i.e., aggregation control unit) through the three-layer network intelligent routing switch, so as to implement network communication and data switching services between the communication base stations or modules.

The multimode intelligent aggregation control unit can be connected into the system and correspondingly arranged and configured. The multimode intelligent aggregation control unit accesses a communication module (namely a first communication module, a second communication module and a WI-FI 6 dual-frequency access station) through a three-layer network intelligent routing switch in the north direction, and accesses a service module (namely a data acquisition terminal, a comprehensive power module, a wireless remote control unit, a shouting module, a lighting module, a comprehensive spectrum sensing module and a heat dissipation management module) in the south direction so as to intelligently integrate the communication module and the service module. Switching strategies among different communication modes can be set, and parameters of the different communication modes can be adjusted so as to complete protocol conversion and data exchange between the first communication module and the second communication module.

The terminal device may be a mobile phone or a computer. The target core network may be an operator core network or a professional core network.

It should be noted that, the three-layer network intelligent routing switch adopts an advanced multistage multi-plane switching architecture, the service board card and the switching network board adopt a completely orthogonal design, the service flow of the line crossing card directly goes to the switching network board through the orthogonal connector, the back board wiring is reduced to zero (signal attenuation can be avoided greatly), the system bandwidth and evolution capability are improved, and the whole capacity can be extended smoothly. The multi-service fusion function module of the switch is innovatively designed to realize the network plug and play and the service automatic deployment and realize the deep fusion of the traditional network and the user service. And dynamically configuring functions, monitoring performance, and troubleshooting switch failures through the network management system.

The multimode intelligent aggregation control unit consists of a power amplifier, an analog-to-digital converter (analog to digital converter, A/D), a micro control unit (microcontroller unit, MCU), a memory and the like, and executes the micro program through a digital channel of the micro sequencer. The instructions can be sequentially fetched from the memory according to a pre-programmed control software control program, placed in the instruction register (instruction register, IR), determined that the next operation should be performed through instruction decoding (analysis), and then micro-operation control signals are sent to corresponding components (such as an LTE public and private base station, a narrow-band digital trunked base station, a comprehensive power module, a 360-degree vision sensor, a megaphone module and the like) according to the determined time sequence through the operation controller (operaTIon controller, OC). The operation controller mainly comprises a beat pulse generator, a control matrix, a clock pulse generator, a reset circuit, a start-stop circuit and other control logic.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 further includes: a data acquisition terminal 17.

Specifically, the data collection terminal 17 is configured to collect target data in the emergency treatment site, and send the target data to the back-end command and dispatch platform through the first communication module 12 and the second communication module 13, where the target data includes at least one of the following: weather-aware data, visual-aware data; the back-end command scheduling platform is used for analyzing and processing the target data to obtain an analysis result and displaying the analysis result to staff; the routing switch 15 is further configured to provide network routing switching services for the data acquisition terminal 17; the aggregation control unit 16 is further configured to control protocol conversion and data exchange among the data acquisition terminal 17, the first communication module 12, and the second communication module 13.

Alternatively, the data acquisition terminal 17 may include a weather sensing module 171 and a 360-degree visual sensing module 172, and the weather sensing data may be acquired by the weather sensing module 171 and the visual sensing data may be acquired by the 360-degree visual sensing module 172. Further, the weather-sensing data and the visual-sensing data are sent to the multi-mode intelligent aggregation control unit, so that the first communication module 12 and the second communication module 13 are controlled by the multi-mode intelligent aggregation control unit to send the weather-sensing data to the back-end command and dispatch platform. The integrated power management, heat dissipation management, local visual sensing, shouting and lighting, wireless remote control, spectrum sensing and other business functions can be completed through the integrated aggregation control unit.

The data acquisition terminal can be configured (including setting a switch state, adjusting parameters and the like) according to actual requirements.

By way of example, the weather-aware data may be wind data, wind direction data, rain data, PM2.5 data, air temperature data; the visual perception data may be audio-video data, distance data, position data. The weather sensing module can be set to be on or off as required; the 360-degree visual sensor can be opened so as to transmit the on-site audio and video conditions to the back-end command scheduling platform in real time.

The weather sensing module has electronic sensing and measuring functions such as wind power, wind direction, rainfall, PM2.5, air temperature and the like, and weather sensing data can be acquired through electronic sensing and measuring work. The 360-degree visual perception module has 6*2 visual sensor multimode visual sensing function, comprehensive sensing service such as dynamic camera shooting and position distance and the like, and can collect data such as position, distance and video.

In one possible implementation, the weather sensing module may perform adaptive optimization of the environment, and the 360-degree vision sensor may be used to identify and track the target.

As one possible implementation, as shown in fig. 1, the first communication module 12 includes a long term evolution LTE public and private base station 121, a narrowband digital trunked base station 122, and an internet of things base station 123, and the second communication module 13 includes a broadband ad hoc network base station 131, an all-network access aggregation module 132, and a high-throughput satellite access module 133.

Specifically, the LTE-public/private base station 121 and the narrowband digital trunking base station 122 are configured to receive a network access signal sent by a terminal device, and send the network access signal to any object of the broadband ad hoc network base station 131, the all-network access aggregation module 132, or the high-throughput satellite access module 133; the internet of things base station 123 is configured to receive the target data sent by the data acquisition terminal 17, and send the target data to any object of the broadband ad hoc network base station 131, the all-network access aggregation module 132, or the high-throughput satellite access module 133.

Optionally, three communication links (including a link for communication by the broadband ad hoc network base station, a link for communication by the all-network access aggregation module, and a link for communication by the high-throughput satellite access module) may be selected for the LTE public-private dual-purpose base station and the narrowband digital trunked base station by the three-layer network intelligent routing switch and the multimode intelligent aggregation control unit, so that the terminal device is accessed to the target core network through the selected communication links.

When the broadband ad hoc network base station is selected to communicate, the terminal equipment can be linked to an area with public network signals based on network access signals sent by the terminal equipment, and the terminal equipment is further accessed to an operator core network gateway through an Internet virtual private network (virtual private network, VPN) channel to become a public network LTE signal base station; or the terminal equipment is accessed to a private network core network gateway to become a private network LTE signal base station.

When the communication is selected through the high-flux satellite access module, the terminal equipment can be accessed to an external high-flux satellite based on a network access signal sent by the terminal equipment, and the terminal equipment is accessed to a target core network gateway through an Internet VPN channel after the terminal equipment is landed; when the communication is selected through the all-network access aggregation access module, the terminal equipment can be accessed to the Internet based on the network access signal sent by the terminal equipment, and the terminal equipment can be accessed to the target core network gateway through the Internet VPN channel.

Three data backhaul links (namely, a link for data backhaul through a broadband ad hoc network base station, a link for data backhaul through a full-network access aggregation module and a link for data backhaul through a high-throughput satellite access module) can be selected for the base station of the internet of things through the three-layer network intelligent routing switch and the multimode intelligent aggregation control unit, so that target data is sent to the back-end command scheduling platform through the selected data backhaul links.

The broadband ad hoc network base station can provide the signal relay service of the ground-to-ground, ground-to-air and air-to-air ad hoc network for the first communication module and the second communication module by adopting an ad hoc network mode through the three-layer network intelligent routing switch and the multi-mode intelligent aggregation control unit, and comprehensively and automatically adjust and allocate resource parameters so as to connect the equipment to a target core network and a back-end command scheduling platform.

The full network access aggregation access module can provide intelligent remote public network signal link service for the first communication module and the second communication module when public network signals (supporting preferential aggregation) are provided through the three-layer network intelligent routing switch and the multi-mode intelligent aggregation control unit, so that the equipment is connected to the target core network and the back-end command scheduling platform.

The high-throughput satellite access module can provide satellite access transmission service for the first communication module and the second communication module through satellite channels under the situation that a public network or an ad hoc network building condition is not provided by the three-layer network intelligent routing switch and the multi-mode intelligent aggregation control unit, so that the equipment is connected to a target core network and a rear-end command scheduling platform.

In the ad hoc network, the nodes communicate by broadcasting and unicast, and data can be transmitted from a source node to a destination node through a plurality of intermediate nodes. Mesh networking protocols include Zigbee, bluetooth Mesh (Bluetooth Mesh), thread, etc. The self-networking network protocol of the aggregation communication system adopts a mesh structure, so that nodes are connected with each other to form a large-scale network, thereby ensuring that the self-networking base station (namely the broadband self-networking base station) of the system can realize communication with the self-networking nodes at the back end through one or more hops.

In one possible implementation manner, an LTE public and private base station may be used to provide communication services for a mobile phone on site; a narrowband digital trunking base station can be used for providing digital trunking communication service for rescue teams; the access and remote control of the Internet of things equipment can be realized by using the Internet of things base station; the interconnection and intercommunication of various communication devices and the back-end command and dispatch platform and service data return can be realized by using a full-network access aggregation access module, a broadband ad hoc network base station or a high-throughput satellite access module.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 further includes: the sixth generation wireless network technology WI-FI 6 dual-frequency access station 14, integrated spectrum sensing module 18 and antenna filtering trap 11.

Specifically, the WI-FI 6 dual-frequency access station 14 is configured to receive a network access signal sent by a terminal device, so as to provide the WI-FI signal for the terminal device based on the network access signal; the integrated spectrum sensing module 18 is configured to collect radio spectrum data generated by the first communication module 12 and radio spectrum data generated by the second communication module 13, and send the radio spectrum data generated by the first communication module 12 and the radio spectrum data generated by the second communication module 13 to the antenna filter trap 11; the antenna filter trap 11 is used for performing a filtering process and a trapping process on the first communication module 12 and the second communication module 13 based on radio spectrum data generated by the first communication module 12 and radio spectrum data generated by the second communication module 13.

Alternatively, suitable antennas and filters may be selected for the co-tuned antenna filter trap (i.e., antenna filter trap) and connected into the aggregate communication system. The antenna filtering trap can comprehensively control and manage frequency selection of communication equipment such as a first communication module, a second communication module, a WI-FI 6 dual-frequency access station and the like according to on-site radio frequency spectrum data perceived by a frequency spectrum perception module, set out-of-band deep filtering on selected frequency of each communication equipment and carry out deep notch processing on related interference sources.

The frequency spectrum sensing module can measure signal parameters such as signal distortion degree, signal modulation degree, frequency spectrum purity, frequency stability, intermodulation distortion and the like and is used for measuring certain parameters of circuit systems such as amplifiers, filters and the like in the base station to obtain radio frequency spectrum data.

The comprehensive spectrum sensing module can be configured according to actual requirements (including setting a switch state and adjusting parameters).

For example, the integrated spectrum sensing module may be set to a real-time monitoring mode in order to discover radio spectrum conditions around the communication module in time.

It should be noted that, the antennas of the narrowband digital trunking base station, the broadband ad hoc network base station, the antennas of the LTE public and private dual-purpose base station, the antennas of the whole network aggregation access module and the antennas of the internet of things base station may be arranged according to a certain rule to form a co-tuned antenna filtering trap array, where the co-tuned antenna filtering trap array is an array antenna formed by an antenna system after filtering processing and optimization of a control unit on a single frequency band antenna. The radiated electromagnetic field of an array antenna is the sum (vector sum) of the radiated fields of the individual elements constituting the antenna array. The position of each unit and the amplitude and phase of the feed current can be independently adjusted and tuned cooperatively.

The frequency spectrum sensing module displays the analysis result in a digital mode and can analyze the electric signal of the required radio frequency band. The digital circuit and MCU processor are adopted in the intelligent test system, and the intelligent test system has the functions of storage and operation and is configured with standard interfaces. The method can optimize the frequency band analysis of the signals of the narrow-band digital trunking base station, the broadband ad hoc network base station and the LTE public and private dual-purpose base station, and simultaneously intelligently close the existing public network frequency band analysis perception in the area, so as to support the problem of the perception optimization of adjacent station interference.

Specifically, the integrated spectrum sensing module 18 is further configured to send the radio spectrum data generated by the first communication module 12 and the radio spectrum data generated by the second communication module 13 to the aggregation control unit; the aggregation control unit is used for analyzing and calculating the radio spectrum data generated by the first communication module 12 and the radio spectrum data generated by the second communication module 13 to obtain a radio carrier calculation result, and sending the radio carrier calculation result to the antenna filtering trap 11; the antenna filter trap 11 is also used for performing antenna fundamental wave processing and antenna harmonic wave processing on the first communication module 12 and the second communication module 13 based on the radio carrier wave calculation result.

Optionally, the integrated spectrum sensing module may perform integrated sensing on related radio spectrums around the first communication module, the second communication module and the WI-FI 6 dual-frequency access station to obtain sensing data (i.e., radio spectrum data), and send the sensing data to the multimode intelligent aggregation control unit, so that based on the sensing data, the multimode intelligent aggregation control unit performs analysis and calculation on multiple radio carriers and performs calculation on main frequency and multiple harmonics of carrier frequencies of each transceiver unit to obtain a radio carrier calculation result.

Furthermore, based on a radio carrier wave calculation result, the first communication module, the second communication module and the WI-FI 6 dual-frequency access station are subjected to frequency spectrum coordination management and filtering notch tuning through the antenna filtering notch filter, so that complete machine electromagnetic compatibility optimization and mutual interference reinforcement suppression are realized, and the filtering notch array is dynamically and cooperatively tuned in an integrated manner, and therefore co-location antenna fundamental wave interference minimization and harmonic interference optimization are realized.

In one possible implementation, the adjustment and optimization of the spectrum signal may be achieved by a comprehensive spectrum sensing module.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 further includes: a shouting module 19 and a lighting module 20.

Specifically, the shouting module 19 is configured to receive, through the first communication module 12 and the second communication module 13, a shouting instruction sent by the back-end command scheduling platform, and perform shouting based on the shouting instruction; the lighting module 20 is configured to receive, through the first communication module 12 and the second communication module 13, a lighting instruction sent by the back-end command dispatch platform, and perform lighting based on the lighting instruction.

Optionally, the multi-mode intelligent aggregation control unit can control the shouting module to receive the shouting instruction sent by the back-end command scheduling platform, and shouting service is performed on the periphery based on the shouting instruction; the multi-mode intelligent aggregation control unit can control the lighting module to receive the lighting instruction sent by the back-end command dispatching platform, and perform lighting service on the periphery based on the lighting instruction.

The shouting module and the lighting module can be configured according to actual requirements (including setting switch states and adjusting parameters).

Illustratively, the megaphone module and the lighting module may be turned on or off as desired.

In one possible implementation, the site may be alerted and guided by the shouting module and the lighting module.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 further includes: an integrated power module 21 and a heat dissipation management module 22.

Specifically, the integrated power module 21 is configured to supply power to the first communication module 12, the second communication module 13, the routing switch 15, the aggregation control unit 16, and the data acquisition terminal 17; the heat dissipation management module 22 is configured to dissipate heat from the first communication module 12, the second communication module 13, the routing switch 15, the aggregation control unit 16, and the data acquisition terminal 17.

Alternatively, integrated power supply and intelligent management services may be provided for individual units and modules in an aggregated communication system by an integrated power module.

In one possible implementation manner, the stable operation of the device can be ensured through the heat dissipation management module.

As one possible implementation, as shown in fig. 1, the aggregate communication system 10 further includes: a wireless remote control unit 23.

Specifically, the wireless remote control unit 23 is configured to determine a target device from the broadband ad hoc network base station, the all-network access aggregation module, or the high-throughput satellite access module, so as to receive network access signals sent by the LTE public/private base station and the narrowband digital trunking base station based on the target device, and receive target data sent by the internet of things base station, where the target device is any object of the broadband ad hoc network base station, the all-network access aggregation module, or the high-throughput satellite access module.

Optionally, a link one-key switching function can be provided through the wireless remote control unit, so that manual and rapid control remote control switching can be performed among three links corresponding to the broadband ad hoc network base station, the all-network access aggregation module and the high-throughput satellite access module.

The embodiment of the application provides an aggregation communication system which intelligently aggregates 17 service modules such as a collaborative tuning antenna filter trap array, an LTE public and private dual-purpose base station, a narrow-band digital cluster base station, a broadband ad hoc network base station, a 5G whole network access aggregation access module, a WI-FI 6 dual-frequency access station, an Internet of things base station, a three-layer network intelligent routing switch, a multi-mode intelligent aggregation control unit, a comprehensive power module, a high-throughput satellite access module, a frequency spectrum sensing module, a wireless remote control unit, a heat dissipation management module, a weather sensing module, a 360-degree visual sensor, a shouting lighting assembly (namely a shouting module and a lighting module) and the like. The application solves the problems that a plurality of devices are needed to be used when carrying out all-element comprehensive communication guarantee, site situation awareness and comprehensive service development in occasions such as emergency rescue and the like, but the devices are difficult to deploy and mutually interfere, and realizes the purposes of meeting interference self-impedance, meeting network self-consistency and one machine to integrally and efficiently complete communication guarantee tasks.

The foregoing description of the solution provided by the embodiments of the present application has been mainly presented in terms of a method. To achieve the above functions, it includes corresponding hardware structures and/or software modules that perform the respective functions. Those of skill in the art will readily appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as hardware or combinations of hardware and computer software. Whether a function is implemented as hardware or computer software driven hardware depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application.

The embodiment of the application can divide the functional modules of a message queue scheduling method according to the method example, for example, each functional module can be divided corresponding to each function, and two or more functions can be integrated in one processing module. The integrated modules may be implemented in hardware or in software functional modules. Optionally, the division of the modules in the embodiment of the present application is schematic, which is merely a logic function division, and other division manners may be implemented in practice.

In the case of implementing the functions of the integrated modules in the form of hardware, the embodiment of the present application provides a possible structural schematic diagram of the electronic device involved in the above embodiment. As shown in fig. 2, an electronic device 60 is provided for improving the efficiency of emergency communications. The electronic device 60 comprises a processor 601, a memory 602 and a bus 603. The processor 601 and the memory 602 may be connected by a bus 603.

The processor 601 is a control center of the communication device, and may be one processor or a collective term of a plurality of processing elements. For example, the processor 601 may be a general-purpose central processing unit (central processing unit, CPU), or may be another general-purpose processor. Wherein the general purpose processor may be a microprocessor or any conventional processor or the like.

As one example, processor 601 may include one or more CPUs, such as CPU 0 and CPU 1 shown in fig. 2.

The memory 602 may be, but is not limited to, a read-only memory (ROM) or other type of static storage device that can store static information and instructions, a random access memory (random access memory, RAM) or other type of dynamic storage device that can store information and instructions, or an electrically erasable programmable read-only memory (EEPROM), magnetic disk storage or other magnetic storage device, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer.

As a possible implementation, the memory 602 may exist separately from the processor 601, and the memory 602 may be connected to the processor 601 through the bus 603 for storing instructions or program codes. The processor 601, when calling and executing instructions or program code stored in the memory 602, is capable of implementing the functions of an aggregate communication system provided by an embodiment of the present application.

In another possible implementation, the memory 602 may also be integrated with the processor 601.

Bus 603 may be an industry standard architecture (industry standard architecture, ISA) bus, a peripheral component interconnect (peripheral component interconnect, PCI) bus, or an extended industry standard architecture (extended industry standard architecture, EISA) bus, among others. The bus may be classified as an address bus, a data bus, a control bus, etc. For ease of illustration, only one thick line is shown in fig. 2, but not only one bus or one type of bus.

It should be noted that the structure shown in fig. 2 does not constitute a limitation of the converged communication gateway 60. The electronic device 60 may include more or fewer components than shown in fig. 2, or may combine certain components or a different arrangement of components.

Optionally, as shown in fig. 2, the electronic device 60 provided by the embodiment of the present application may further include a communication interface 604.

Communication interface 604 for connecting with other devices via a communication network. The communication network may be an ethernet, a radio access network, a wireless local area network (wireless local area networks, WLAN), etc. The communication interface 604 may include a receiving unit for receiving data and a transmitting unit for transmitting data.

In one design, the electronic device provided in the embodiment of the present application may further include a communication interface integrated in the processor.

From the above description of embodiments, it will be apparent to those skilled in the art that the foregoing functional unit divisions are merely illustrative for convenience and brevity of description. In practical applications, the above-mentioned function allocation may be performed by different functional units, i.e. the internal structure of the device is divided into different functional units, as needed, to perform all or part of the functions described above. The specific operation of the above-described system, device and module may refer to the description in the foregoing embodiments, which are not repeated here.

The embodiment of the application also provides a computer readable storage medium, wherein the computer readable storage medium stores instructions, when the computer executes the instructions, the computer executes the functions of the aggregation communication system.

Embodiments of the present application provide a computer program product comprising instructions which, when run on a computer, cause the computer to perform the functions of the aggregate communication system described above.

The computer readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or a combination of any of the foregoing. More specific examples (a non-exhaustive list) of the computer-readable storage medium would include the following: electrical connections having one or more wires, portable computer diskette, hard disk. Random access memory (random access memory, RAM), read-only memory (ROM), erasable programmable read-only memory (erasable programmable read only memory, EPROM), registers, hard disk, optical fiber, portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any other form of computer-readable storage medium suitable for use by a person or combination of the foregoing, or as a value in the art. An exemplary storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an application specific integrated circuit (application specific integrated circuit, ASIC). In embodiments of the present application, a computer readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device.

The present application is not limited to the above embodiments, and any changes or substitutions within the technical scope of the present application should be covered by the scope of the present application.

Claims (10)

1. An aggregate communication system, the aggregate communication system comprising: the device comprises a first communication module, a second communication module, a routing switch and an aggregation control unit;

the first communication module is used for receiving a network access signal sent by a terminal device in an emergency disposal site and sending the network access signal to the second communication module;

the second communication module is configured to receive the network access signal sent by the first communication module, so as to access the terminal device to a target core network based on the network access signal;

the routing switch is used for providing network routing switching service for the first communication module, the second communication module and the aggregation control unit;

the aggregation control unit is used for controlling protocol conversion and data exchange between the first communication module and the second communication module.

2. The aggregate communication system of claim 1, further comprising: a data acquisition terminal;

The data acquisition terminal is used for acquiring target data in an emergency treatment site, and sending the target data to the back-end command scheduling platform through the first communication module and the second communication module, wherein the target data comprises at least one of the following: weather-aware data, visual-aware data;

the back-end command scheduling platform is used for analyzing and processing the target data to obtain an analysis result and displaying the analysis result to staff;

the routing switch is also used for providing network routing switching service for the data acquisition terminal;

the aggregation control unit is also used for controlling protocol conversion and data exchange among the data acquisition terminal, the first communication module and the second communication module.

3. The aggregation communication system according to claim 1 or 2, wherein the first communication module comprises a long term evolution, LTE, public and private, base station, a narrowband digital trunked base station, and an internet of things base station, and the second communication module comprises a broadband ad hoc network base station, a full network access aggregation access module, and a high throughput satellite access module;

the LTE public and private dual-purpose base station and the narrow-band digital trunking base station are used for receiving the network access signal sent by the terminal equipment and sending the network access signal to any object in the broadband ad hoc network base station, the all-network access aggregation access module or the high-throughput satellite access module;

The internet of things base station is used for receiving the target data sent by the data acquisition terminal and sending the target data to any object in the broadband ad hoc network base station, the all-network access aggregation module or the high-throughput satellite access module.

4. The aggregate communication system of claim 1 or 2, further comprising: a sixth generation wireless network technology WI-FI 6 dual-frequency access station, a comprehensive spectrum sensing module and an antenna filtering trap;

the WI-FI 6 dual-frequency access station is configured to receive the network access signal sent by the terminal device, so as to provide a WI-FI signal for the terminal device based on the network access signal;

the comprehensive spectrum sensing module is used for collecting radio spectrum data generated by the first communication module and radio spectrum data generated by the second communication module, and sending the radio spectrum data generated by the first communication module and the radio spectrum data generated by the second communication module to the antenna filtering trap;

the antenna filtering wave trap is used for carrying out filtering processing and wave trapping processing on the first communication module and the second communication module based on radio spectrum data generated by the first communication module and radio spectrum data generated by the second communication module.

5. The aggregate communication system of claim 4, wherein the integrated spectrum sensing module is further configured to send radio spectrum data generated by the first communication module and radio spectrum data generated by the second communication module to the aggregate control unit;

the aggregation control unit is used for analyzing and calculating the radio spectrum data generated by the first communication module and the radio spectrum data generated by the second communication module to obtain a radio carrier calculation result, and sending the radio carrier calculation result to the antenna filtering trap;

the antenna filtering trap is further used for performing antenna fundamental wave processing and antenna harmonic wave processing on the first communication module and the second communication module based on the radio carrier wave calculation result.

6. The aggregate communication system of claim 1 or 2, further comprising: a shouting module and a lighting module;

the shouting module is used for receiving the shouting instruction sent by the back-end command scheduling platform through the first communication module and the second communication module and shouting based on the shouting instruction;

The illumination module is used for receiving the illumination instruction sent by the back-end command scheduling platform through the first communication module and the second communication module, and illuminating based on the illumination instruction.

7. The aggregate communication system of claim 1 or 2, further comprising: a comprehensive power module and a heat dissipation management module;

the comprehensive power supply module is used for supplying power to the first communication module, the second communication module, the routing switch, the aggregation control unit and the data acquisition terminal;

the heat dissipation management module is used for dissipating heat for the first communication module, the second communication module, the routing switch, the aggregation control unit and the data acquisition terminal.

8. The aggregate communication system of claim 3, further comprising: a wireless remote control unit;

the wireless remote control unit is used for determining target equipment from the broadband ad hoc network base station, the all-network access aggregation module or the high-throughput satellite access module, so as to receive the network access signal sent by the LTE public and private base station and the narrowband digital trunking base station and receive the target data sent by the Internet of things base station based on the target equipment, wherein the target equipment is any object of the broadband ad hoc network base station, the all-network access aggregation module or the high-throughput satellite access module.

9. An electronic device, comprising: a processor and a memory; wherein the memory is configured to store one or more programs, the one or more programs comprising computer-executable instructions that, when executed by the electronic device, cause the electronic device to perform a method corresponding to an aggregate communication system of any of claims 1-8.

10. A computer readable storage medium storing one or more programs, wherein the one or more programs comprise instructions, which when executed by a computer, cause the computer to perform a method of an aggregate communication system of any of claims 1-8.