Hybrid wireless networking control system
Technical Field
The invention relates to the technical field of wireless networking, in particular to a hybrid wireless networking control system.
Background
The wireless networking module is also called as a wireless ad hoc network module, is a module for carrying out wireless data transmission by utilizing a wireless technology, is a temporary multi-hop autonomous system consisting of a group of movable nodes with wireless transmitting and receiving devices, does not depend on preset infrastructure, has the characteristics of temporary networking, quick expansion, no control center, strong survivability and the like, has wide application prospect in military, civil and civil aspects, and is a hotspot problem in network research.
At present, most of households are only provided with a router at home to realize the connection of a wireless network, because the coverage area of the router is small, when the household moves to the coverage edge of the router, signals can be poor, even the internet surfing operation can not be carried out, and in order to realize the full coverage of the wireless network, some households can be provided with routers in other rooms for bridging, although the network names are consistent, the network names are multiple signal sources, when the household moves from one signal source to another signal source, the wireless signals of a mobile phone can realize automatic switching, but the network is in a disconnected state in the switching process, so that the user experience is poor. Therefore, a hybrid wireless networking control system is provided.
Disclosure of Invention
The present invention is directed to a hybrid wireless networking control system to solve the problems set forth in the background art.
In order to achieve the purpose, the invention provides the following technical scheme: a hybrid wireless networking control system, comprising: the base station is provided with an optical fiber with one end connected with the base station, the other end of the optical fiber is connected with an optical modem arranged in a weak electric box, the optical modem is provided with a first network cable with one end connected with the optical modem, the other end of the first network cable is connected with a lora terminal arranged in the living room, the first network cable is connected with a WAN port of a lora terminal, a second network cable with one end connected with the LAN port of the lora terminal is arranged on the LAN port of the lora terminal, the other end of the second network cable is connected with a switch, a plurality of groups of third network cables with one ends connected with the switch are arranged on the switch, the other end of the third network cable is connected with a plurality of routers arranged in each room, so that the problems of small coverage area and poor signal of the original wireless signals are solved, and the problem of poor experience caused by influence on use of users when the original multi-group signal sources are switched is also solved.
Preferably, the base station is a lora self-built base station, which is beneficial to improving the coverage area and the safety of wireless signals.
Preferably, the lora terminal comprises a plurality of groups of nodes, each node comprises a data processing control module, a data encryption and decryption module and a data transceiving module, and the plurality of connected nodes of the lora terminal have advantages.
Preferably, the data processing control module is configured to parse and convert data into a control signal for the device, and package and encapsulate a data packet to be sent; the data encryption and decryption module is used for encrypting and decrypting the data packet; the data transceiver module is communicated with the router and exchanges data with adjacent nodes.
Preferably, the plurality of routers are all routers supporting bluetooth mesh and KVR roaming protocols, and mobile phone control and seamless network switching are facilitated.
Preferably, a plurality of the routers are controlled by a mobile phone end through APP software, so that the mobile phone can conveniently control the home network.
Preferably, the first network cable, the second network cable and the third network cable are all over 6 types of ten-thousand million network cables, so that the service life of the whole network cable is prolonged, and the network cable is more durable.
A hybrid wireless networking control system specifically comprises the following steps of:
s1: the mobile phone terminal end nodes collects bottom layer data, the data are sent to a Gateway (Gateway) base station through a Radio Frequency (RF) technology/LoRaWAN technology and then sent to a Network Server (NS) through a communication technology (3 g/Ethernet), the NS sends the data to an application program terminal (APP), and the program terminal can respectively control a plurality of routers.
S2: the base station transmits signals to the optical modem through optical fibers, the optical modem converts the optical signals into electric signals and transmits the electric signals to the lora terminal through the first network cable, the lora terminal is provided with a plurality of groups of nodes, the nodes respectively pass through the data processing control module, the data encryption module and the data receiving and transmitting module, and the lora terminal transmits the signals to the switch through the second network cable.
S3: after the switch receives the signals, the signals are respectively transmitted to the routers through the multiple groups of third network lines, so that each router can provide strong wireless signals, the whole house is covered, seamless butt joint can be realized among the routers through a KVR roaming protocol, and the situation of short-time network disconnection can not occur no matter which router is connected with the mobile phone terminal.
Compared with the prior art, the invention has the beneficial effects that:
according to the invention, by arranging a group of outdoor-to-indoor hybrid wireless networking, the problems of small coverage area and poor signal of the original wireless signal are solved, the problem of poor experience caused by influence on the use of a user when switching among a plurality of groups of original signal sources is also solved, the coverage range of the wireless signal is improved by applying the lora technology and the Bluetooth technology, the overall safety is also improved, meanwhile, the power consumption is reduced, and the overall practicability and the experience of the user are effectively improved.
Drawings
FIG. 1 is a schematic view of the overall structure of the present invention.
In the figure: 1-a base station; 2-an optical fiber; 3-light cat; 4-a first network cable; 5-lora terminal; 6-a second network cable; 7-a switch; 8-a third mesh wire; 9-router.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Example 1
Referring to fig. 1, the present invention provides a technical solution: a hybrid wireless networking control system, comprising: the base station comprises a base station 1, an optical fiber 2 with one end connected with the base station 1 is arranged on the base station 1, the other end of the optical fiber 2 is connected with an optical modem 3 arranged in a weak electric box, a first network cable 4 with one end connected with the optical modem 3 is arranged on the optical modem 3, the other end of the first network cable 4 is connected with a lora terminal 5 arranged in a living room, the first network cable 4 is connected with a WAN port of the lora terminal 5, a second network cable 6 with one end connected with the lora terminal 5 is arranged on a LAN port of the lora terminal 5, the other end of the second network cable 6 is connected with a switch 7, a plurality of groups of third network cables 8 with one ends connected with the switch 7 are arranged on the switch 7, the other ends of the third network cables 8 are connected with a plurality of routers 9 arranged in each room respectively, and the base station 1 is a lora self-building base station 1.
The lora terminal 5 comprises a plurality of groups of nodes, wherein each node comprises a data processing control module, a data encryption and decryption module and a data transceiving module, and the data processing control module is used for analyzing and converting data into a control signal for equipment and packaging a data packet to be sent; the data encryption and decryption module is used for encrypting and decrypting the data packet; the data transceiver module communicates with the router 9 and exchanges data with the adjacent nodes.
The routers 9 are all routers 9 supporting mesh and KVR roaming protocols, the routers 9 are all controlled by a mobile phone end through APP software, and the first network cable 4, the second network cable 6 and the third network cable 8 are all ultra-6-class ten-gigabit network cables.
The optical fiber 2 is connected with a base station 1 arranged outdoors, the other end of the optical fiber is connected with an optical modem 3, the optical modem 3 converts an optical signal into an electric signal and is simultaneously connected with a WAN interface on a lora terminal 5 through a first network cable 4, a second network cable 6 connects a LAN port on the lora terminal 5 with a switch 7, the switch 7 is connected with a plurality of indoor routers 9 through a plurality of third network cables 8, so that a wired return mesh between a plurality of groups of routers 9 and the lora terminal 5 is formed, the coverage range is large, the signal is strong, the routers 9 are provided with Bluetooth meshes, the respective independent control of mobile phone ends can be realized, the function of a KVR roaming protocol can realize seamless butt joint, when people walk to another room with the routers 9 from the room with one group of routers 9, the seamless butt joint of network switching can not affect the current use.
A hybrid wireless networking control system specifically comprises the following steps of:
s1: the mobile phone terminal end nodes collects bottom layer data, the data are sent to a Gateway (Gateway) base station through a radio frequency technology/LoRaWAN technology and then sent to a Network Server (NS) through a communication technology (3 g/Ethernet), the NS sends the data to an application program terminal (APP), and the program terminal can respectively control a plurality of routers 9.
S2: the base station 1 transmits signals to the optical modem 3 through the optical fiber 2, the optical modem 3 converts the optical signals into electric signals and transmits the electric signals to the lora terminal 5 through the first network cable 4, the lora terminal 5 is provided with a plurality of groups of nodes, the nodes respectively pass through the data processing control module, the data encryption module and the data receiving and transmitting module, and the lora terminal 5 transmits the signals to the switch 7 through the second network cable 6.
S3: after receiving the signals, the switch 7 transmits the signals to the routers 9 through the multiple groups of third network lines 8, so that each router 9 can provide strong wireless signals, the whole house is covered, seamless butt joint can be realized between the routers 9 through a KVR roaming protocol, and the situation of short-time network disconnection of the mobile phone terminal can not occur no matter which router 9 is connected.
Example 2
A hybrid wireless networking control system specifically comprises the following steps of:
s1: the mobile phone terminal end nodes collects bottom layer data, the data are sent to the platform through a Radio Frequency (RF) technology/LoRaWAN technology, and the platform transmits signals to the main gateway through optical fibers or 5G.
S2: after receiving the signals, the main gateway transmits the signals to the routing gateways through LoRa technology or wifi, and the multiple groups of routing gateways are communicated with each other.
S3: after receiving the signals, the multiple groups of routing gateways transmit the signals to multiple groups of routing nodes in the home room, the multiple groups of routing nodes are mesh networks and are communicated with each other, and the routing nodes are communicated with the routing gateways at the same time to form seamless switching.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.