CN117395693A - High-reliability router, fusion method and equipment - Google Patents

Abstract

The invention provides a high-reliability router, a fusion method and equipment. The high-reliability router comprises a main control chip, a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and a USB interface group; the main control chip is used for controlling the high-reliability router to continuously detect the network conditions of the wireless cellular and the wired broadband, obtaining the network operation conditions of the wireless cellular and the wired broadband, splitting the network data packet to form a plurality of data messages, and transmitting the plurality of data messages to a designated server through the evaluated network and by utilizing a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and/or a USB interface group; the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group are all used for sending the data message formed by splitting to a designated server.

Description

High-reliability router, fusion method and equipment

Technical Field

The invention relates to a high-reliability router, a fusion method and equipment, and belongs to the technical field of communication.

Background

In the mobile payment scenario, the cashing device needs to have reliable network connection, however, the current basic mobile payment environment and scenario are all network connection by using a single network mode, and the single broadband network or the 4G/5G network always has network faults, so that network interruption of cashing and other service systems is caused.

Disclosure of Invention

The invention provides a high-reliability router based on the integration of a wired broadband and a cellular wireless network, an integration method and equipment, which are used for solving the problem that a single network payment environment is easy to cause network interruption, and the adopted technical scheme is as follows:

the high-reliability router comprises a main control chip, a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and a USB interface group; the signal output of the main control chip is respectively connected with the control signal input ends of the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group;

the main control chip is used for controlling the high-reliability router to continuously detect the network conditions of the wireless cellular and the wired broadband, obtaining the network operation conditions of the wireless cellular and the wired broadband, connecting the terminal with the equipment, splitting the network data packet to form a plurality of data messages, and transmitting the plurality of data messages to the appointed server through the evaluated network; each data message corresponds to one path of network node, and each path of honeycomb 4GUSB Dongle of the network node which is a multipath aggregation router is a node, and a wired broadband is a node; after the designated server receives the data message, the data message is spliced and restored to form a complete network data packet; forwarding the complete network data packet to a destination server;

the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group are all used for sending the data message formed by splitting to a designated server.

Further, the first wireless network interface group comprises one or more wifi wireless interface modules formed by one or more wifi chips.

Further, the second wireless network interface group includes one or more 4G wireless interface modules formed by one or more 4G modules.

Further, the third wireless network interface group includes one or more WLAN wireless interface modules formed by one or more WLAN modules.

Further, the USB interface group includes one or more USB interfaces.

A method of fusing a highly reliable router, the method comprising:

the high-reliability router continuously detects the network conditions of wireless cells and wired broadband, and obtains the network operation conditions of the wireless cells and the wired broadband;

splitting a request of connecting a terminal with equipment to form a plurality of data messages by a network data packet, and transmitting the plurality of data messages to a designated server by an evaluated network; wherein, each data message corresponds to a path of network Node, each path of cellular 4G USB Dongle of the network Node which is a multipath aggregation router is a Node, and the wired broadband is a Node;

after the designated server receives the data message, the data message is spliced and restored to form a complete network data packet;

and forwarding the complete network data packet to a destination server.

Further, the high reliability router continuously detects network conditions of wireless cells and wired broadband, and obtains network operation conditions of the wireless cells and the wired broadband, including:

the high-reliability router continuously detects network conditions of wireless cells and wired broadband and obtains operation parameters of the wireless cells and the wired broadband;

the high-reliability router obtains the network operation conditions of the wireless cellular and the wired broadband by utilizing the operation parameters of the wireless cellular and the wired broadband in combination with a network evaluation model;

the network evaluation model comprises a wireless cellular operation evaluation model and a wired broadband operation evaluation model;

wherein the wireless cellular operation assessment model is as follows:

Q ₀₁ ＝w ₁ ·Q ₁₁ +w ₂ ·Q ₁₂ +w ₃ ·Q ₁₃ +w ₄ ·Q ₁₄

Q ₁₂ ＝(Q ₁₁ -N _p )·[(Q _11max -N _pmax )·B _r ] ^-1

Q ₁₃ ＝(1-E _r )·100％

wherein Q is ₀₁ Network operation evaluation parameters representing a wireless cell between a terminal and a device; q (Q) ₁₁ Representing signal strength evaluation parameters; q (Q) ₁₂ Representing a signal quality evaluation parameter; q (Q) ₁₃ Representing a frequency band quality evaluation parameter; q (Q) ₁₄ Representing data transmission rate evaluation parameters; w (w) ₁ 、w ₂ 、w ₃ And w ₄ Respectively representing weights corresponding to the signal strength evaluation parameter, the signal quality evaluation parameter, the frequency band quality evaluation parameter and the data transmission rate evaluation parameter; n represents the number of interference sources; l (L) _i Representing the interference strength (in dBm) of an ith interference source to the device; d (D) _i Representing a linear distance between an ith interference source and the device; w (W) _0i Representing the weight corresponding to the ith interference source; p represents the actual signal power of the signal received by the device; p (P) ₀ Representing a preset signal power threshold; a represents the signal reception sensitivity (in dBm) of the device; u represents the number of barriers between the terminal and the equipment; d (D) _ui Representing a linear distance between an ith obstacle and the device; h _i Representing the height of the ith obstacle; h ₀ Representing that the height of the obstacle reaches the height corresponding to the minimum of signal space propagation interference; n (N) _p Representing the noise level (detectable by the instrument) in the environment in which the device is located; q (Q) _11max Representing the maximum value of signal intensity that occurs until the current evaluation; n (N) _pmax Representing the highest value of noise level in the environment in which the device is located; b (B) _r Representing the ratio between signal and noise; e (E) _r Representing the bit error rate, i.e. the ratio of the number of erroneous bits received by the device to the total number of bits transmitted; q (Q) ₄₀ Representing a preset rate evaluation reference index value; r is R ₀ Representing a preset channel data transmission rate threshold; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; r is R _min Representing an actual data transmission rate minimum of a channel between the device and the terminal; s represents the number of channels between the device and the terminal;

the wired broadband operation evaluation model is as follows:

wherein Q is ₀₂ Network operation evaluation parameters representing a wired broadband between the terminal and the device; v (V) _x 、V _s And V _l Respectively representing the data downloading rate, the data uploading rate and the network connection rate of the terminal; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; q (Q) ₂ Representing a preset network operation evaluation parameter reference value of the wired broadband; p (P) _a Indicating the probability of successful data connection between the terminal and the device.

Further, the request of the terminal connection device is split into a plurality of data messages by splitting the network data packet, including:

receiving a connection request sent by the terminal connection device in real time, wherein the connection request comprises network resources (network transmission rate) required by the terminal connection device;

and determining the splitting quantity of the network data packet split into a plurality of data messages currently by combining the connection request sent by the terminal connection equipment and the network resource parameter corresponding to each network node through the unpacking quantity setting model.

Further, the unpacking number setting model is as follows:

wherein M represents the split number of the data message; k (K) _m Representing the total number of network nodes; c represents the data volume of the network data packet; p (P) _a The probability of successful data connection between the terminal and the equipment is represented; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; s denotes the number of channels between the device and the terminal.

The equipment utilizing any one of the high-reliability routers is characterized by comprising a user terminal, the high-reliability router, an ADSL device, a router and a cloud server; the user terminal is in data connection with the high-reliability router; the high-reliability router is respectively connected with the ADSL device and the cloud server in a data mode; the ADSL device is in data connection with the router; the router is in data connection with the cloud server; the high-reliability router adopts any one of the high-reliability routers.

The invention has the beneficial effects that:

the high-reliability router and the equipment provided by the invention have the following technical effects: first, improving the network bandwidth utilization: through the multiplexing scheme, a plurality of network connections can be used simultaneously, network resources are fully utilized, and the bandwidth utilization rate is improved. Second, network stability is improved: because a plurality of network connections are operated simultaneously, once one network connection has a problem, other connections can still maintain data transmission, and the stability of the network is improved. Thirdly, solving the problems of unstable signals and unstable network transmission: in the case of a single 4/5G cellular network or a broadband network, the problems of signal instability and network transmission instability due to various restrictions can be solved by means of multiplexing. Fourth, network reliability is improved: the bottom layer of the technology adopts a centralized directory P2P mode, processes data packets at a TCP/IP layer, unpacks and distributes the data packets to a designated IP address through a target IP distributed by a central record server, and combines services where the IP address is located, thereby constructing a more reliable network

Drawings

FIG. 1 is a schematic diagram of a high reliability router according to the present invention;

FIG. 2 is a flow chart of a high reliability router according to the present invention;

FIG. 3 is a schematic diagram illustrating the operation of a high reliability router according to the present invention;

fig. 4 is a schematic structural diagram of an apparatus of the high reliability router according to the present invention.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

The embodiment of the invention provides a high-reliability router, as shown in fig. 1, which comprises a main control chip, a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and a USB interface group; and the signal output of the main control chip is respectively connected with the control signal input ends of the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group. The main control chip is used for controlling the high-reliability router to continuously detect the network conditions of the wireless cellular and the wired broadband, obtaining the network operation conditions of the wireless cellular and the wired broadband, connecting the terminal with the equipment, splitting the network data packet to form a plurality of data messages, and transmitting the plurality of data messages to the appointed server through the evaluated network; wherein, each data message corresponds to a path of network node, each path of cellular 4G USB Dongle of the network node which is a multipath aggregation router is a node, and a wired broadband is a node; after the designated server receives the data message, the data message is spliced and restored to form a complete network data packet; and forwarding the complete network data packet to a destination server.

The first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group are all used for sending the data message formed by splitting to a designated server.

The first wireless network interface group comprises one or more wifi wireless interface modules formed by one or more wifi chips. The second wireless network interface group includes one or more 4G wireless interface modules formed by one or more 4G modules. The third wireless network interface group includes one or more WLAN wireless interface modules formed by one or more WLAN modules. The USB interface group includes one or more USB interfaces.

The working principle of the technical scheme is as follows: the embodiment adopts the technical scheme that the broadband and a plurality of cellular networks are mutually reserved, and a user can use broadband connection as a common router under the condition that a high-reliability network is not needed; if the user needs reliable connection, the broadband can be connected and a plurality of 4G USB dongles can be inserted, the equipment can mutually prepare with the broadband network through the 4G USB dongles connection network, and the plurality of 4G USB dongles can also mutually prepare.

In addition, multiple 4G USB dongles and broadband may be selectively aggregated, and network bandwidths may be aggregated concurrently (for example, the broadband is 100Mbps, one 4G USB Dongle is 50Mbps, and if 3 4G USB dongles are connected, the total bandwidth is 100+50×3=250 Mbps).

Specifically, the bottom layer of the multi-path aggregation mode adopts a centralized directory P2P mode, processes data packets at the TCP/IP layer, unpacks and distributes the data packets to a designated IP address through a target IP distributed by a central record server, and combines services where the IP address is located. Each path of cellular 4G USB Dongle of the multipath aggregation router is a Node, the wired broadband is a Node, the local nodes do not perform P2P communication, and the nodes and the IP designated by the server perform P2P communication.

The method can fully utilize network resources, and solves the problem of unstable network transmission caused by unstable signals due to various limitations under the condition of a single 4/5G cellular network or a broadband network by a multiplexing mode. And the network constructed in this mode is more reliable.

The technical scheme has the effects that: first, improving the network bandwidth utilization: through the multiplexing scheme, a plurality of network connections can be used simultaneously, network resources are fully utilized, and the bandwidth utilization rate is improved. Second, network stability is improved: because a plurality of network connections are operated simultaneously, once one network connection has a problem, other connections can still maintain data transmission, and the stability of the network is improved. Thirdly, solving the problems of unstable signals and unstable network transmission: in the case of a single 4/5G cellular network or a broadband network, the problems of signal instability and network transmission instability due to various restrictions can be solved by means of multiplexing. Fourth, network reliability is improved: the technical bottom layer adopts a centralized directory P2P mode, processes data packets at a TCP/IP layer, unpacks and distributes the data packets to a designated IP address through a target IP distributed by a central record server, and combines services where the IP address is located, thereby constructing a more reliable network.

In one embodiment of the present invention, as shown in fig. 2 and 3, the fusion method of the high reliability router includes:

s1, continuously detecting network conditions of wireless cells and wired broadband by the high-reliability router to obtain network operation conditions of the wireless cells and the wired broadband;

s2, splitting a request of connecting equipment of a terminal into a plurality of data messages through a network data packet, and transmitting the plurality of data messages to a designated server through an evaluated network; wherein, each data message corresponds to a path of network Node, each path of cellular 4G USB Dongle of the network Node which is a multipath aggregation router is a Node, and the wired broadband is a Node;

s3, after the designated server receives the data message, splicing and restoring the data message to form a complete network data packet;

s4, forwarding the complete network data packet to a destination server.

The method for obtaining the network operation conditions of the wireless cellular and the wired broadband by using the high-reliability router continuously detects the network conditions of the wireless cellular and the wired broadband comprises the following steps:

s101, continuously detecting network conditions of a wireless honeycomb and a wired broadband by the high-reliability router, and acquiring operation parameters of the wireless honeycomb and the wired broadband;

s102, the high-reliability router utilizes the operation parameters of the wireless cellular and the wired broadband to combine with a network evaluation model to obtain the network operation conditions of the wireless cellular and the wired broadband;

when the network operation evaluation parameters corresponding to the network operation conditions of the wireless cellular and the wired broadband are lower than a preset parameter threshold, carrying out abnormal alarm on the network operation conditions;

the network evaluation model comprises a wireless cellular operation evaluation model and a wired broadband operation evaluation model;

wherein the wireless cellular operation assessment model is as follows:

Q ₀₁ ＝w ₁ ·Q ₁₁ +w ₂ ·Q ₁₂ +w ₃ ·Q ₁₃ +w ₄ ·Q ₁₄

Q ₁₂ ＝(Q ₁₁ -N _p )·[(Q _11max -N _pmax )·B _r ] ^-1

Q ₁₃ ＝(1-E _r )·100％

wherein Q is ₀₁ Network operation evaluation parameters representing a wireless cell between a terminal and a device; q (Q) ₁₁ Representing signal strength evaluation parameters; q (Q) ₁₂ Representing a signal quality evaluation parameter; q (Q) ₁₃ Representing a frequency band quality evaluation parameter; q (Q) ₁₄ Representing data transmission rate evaluation parameters; w (w) ₁ 、w ₂ 、w ₃ And w ₄ Respectively representing weights corresponding to the signal strength evaluation parameter, the signal quality evaluation parameter, the frequency band quality evaluation parameter and the data transmission rate evaluation parameter; n represents the number of interference sources; l (L) _i Representing the interference strength (in dBm) of an ith interference source to the device; d (D) _i Representing a linear distance between an ith interference source and the device; w (W) _0i Representing the weight corresponding to the ith interference source; p represents the actual signal power of the signal received by the device; p (P) ₀ Representing a preset signal power threshold; a represents the signal reception sensitivity (in dBm) of the device; u represents the number of barriers between the terminal and the equipment; d (D) _ui Representing a linear distance between an ith obstacle and the device; h _i Representing the height of the ith obstacle; h ₀ Representing that the height of the obstacle reaches the height corresponding to the minimum of signal space propagation interference; n (N) _p Representing the noise level (detectable by the instrument) in the environment in which the device is located; q (Q) _11max Representing the maximum value of signal intensity that occurs until the current evaluation; n (N) _pmax Representing the highest value of noise level in the environment in which the device is located; b (B) _r Representing the ratio between signal and noise; e (E) _r Representing the bit error rate, i.e. the ratio of the number of erroneous bits received by the device to the total number of bits transmitted; q (Q) ₄₀ Representing a preset rate evaluation reference index value; r is R ₀ Representing a preset channel data transmission rate threshold; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; r is R _min Representing an actual data transmission rate minimum of a channel between the device and the terminal; s represents the information between the device and the terminalNumber of lanes;

the wired broadband operation evaluation model is as follows:

wherein Q is ₀₂ Network operation evaluation parameters representing a wired broadband between the terminal and the device; v (V) _x 、V _s And V _l Respectively representing the data downloading rate, the data uploading rate and the network connection rate of the terminal; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; q (Q) ₂ Representing a preset network operation evaluation parameter reference value of the wired broadband; p (P) _a Indicating the probability of successful data connection between the terminal and the device.

By combining various network operation parameters in the mode, the accuracy of network operation condition evaluation of the wireless cellular and the wired broadband can be effectively improved, meanwhile, the following performance of the network operation condition evaluation of the wireless cellular and the wired broadband and the actual network operation condition is effectively improved, and the problem that the accuracy of the network operation condition evaluation of the wireless cellular and the wired broadband is reduced due to the fact that the actual network operation condition evaluation of the wireless cellular and the wired broadband cannot be timely obtained due to the fact that the following performance of the network operation condition evaluation of the wireless cellular and the wired broadband is low is solved.

Wherein, the request of the terminal connection device is split into a plurality of data messages by splitting the network data packet, which comprises:

s201, receiving a connection request sent by the terminal connection equipment in real time, wherein the connection request comprises network resources (network transmission rate) required by the terminal connection equipment;

s202, determining the splitting number of the network data packet split into a plurality of data messages currently by combining a connection request sent by the terminal connection equipment and network resource parameters corresponding to each network node through a unpacking number setting model.

Wherein the unpacking quantity setting model is as follows:

wherein M represents the split number of the data message; k (K) _m Representing the total number of network nodes; c represents the data volume of the network data packet; p (P) _a The probability of successful data connection between the terminal and the equipment is represented; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; s denotes the number of channels between the device and the terminal.

The technical scheme has the effects that: through the multiplexing scheme, a plurality of network connections can be used simultaneously, network resources are fully utilized, and the bandwidth utilization rate is improved. Because a plurality of network connections are operated simultaneously, once one network connection has a problem, other connections can still maintain data transmission, and the stability of the network is improved. In the case of a single 4/5G cellular network or a broadband network, the problems of signal instability and network transmission instability due to various restrictions can be solved by means of multiplexing. Fourth, network reliability is improved: the technical bottom layer adopts a centralized directory P2P mode, processes data packets at a TCP/IP layer, unpacks and distributes the data packets to a designated IP address through a target IP distributed by a central record server, and combines services where the IP address is located, thereby constructing a more reliable network.

On the other hand, the rationality of the unpacking quantity setting can be effectively improved through the unpacking quantity setting model, the problem that network resources are excessively scattered due to the fact that the unpacking quantity is too large, and then resource waste is caused is solved, and meanwhile the problem that the resource utilization rate is reduced due to the fact that the unpacking quantity is too small is prevented.

In one embodiment of the present invention, as shown in fig. 4, a device based on a high-reliability router where a wired broadband and a cellular wireless network are integrated, where the device includes a user terminal, a high-reliability router, an ADSL device, a router, and a cloud server; the user terminal is in data connection with the high-reliability router; the high-reliability router is respectively connected with the ADSL device and the cloud server in a data mode; the ADSL device is in data connection with the router; the router is in data connection with the cloud server; the high reliability router employs any of the high reliability routers of the embodiments.

The embodiment of the invention provides a high-reliability router based on the integration of a wired broadband and a cellular wireless network, wherein the high-reliability router comprises a main control chip, a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and a USB interface group; and the signal output of the main control chip is respectively connected with the control signal input ends of the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group.

The first wireless network interface group comprises one or more wifi wireless interface modules formed by one or more wifi chips. The second wireless network interface group includes one or more 4G wireless interface modules formed by one or more 4G modules. The third wireless network interface group includes one or more WLAN wireless interface modules formed by one or more WLAN modules. The USB interface group includes one or more USB interfaces.

The technical scheme has the effects that: first, improving the network bandwidth utilization: through the multiplexing scheme, a plurality of network connections can be used simultaneously, network resources are fully utilized, and the bandwidth utilization rate is improved. Second, network stability is improved: because a plurality of network connections are operated simultaneously, once one network connection has a problem, other connections can still maintain data transmission, and the stability of the network is improved. Thirdly, solving the problems of unstable signals and unstable network transmission: in the case of a single 4/5G cellular network or a broadband network, the problems of signal instability and network transmission instability due to various restrictions can be solved by means of multiplexing. Fourth, network reliability is improved: the technical bottom layer adopts a centralized directory P2P mode, processes data packets at a TCP/IP layer, unpacks and distributes the data packets to a designated IP address through a target IP distributed by a central record server, and combines services where the IP address is located, thereby constructing a more reliable network.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. The high-reliability router is characterized by comprising a main control chip, a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and a USB interface group; the signal output of the main control chip is respectively connected with the control signal input ends of the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group;

the main control chip is used for controlling the high-reliability router to continuously detect the network conditions of the wireless cellular and the wired broadband, obtaining the network operation conditions of the wireless cellular and the wired broadband, splitting the network data packet to form a plurality of data messages, and transmitting the plurality of data messages to a designated server through the evaluated network and by utilizing a first wireless network interface group, a second wireless network interface group, a third wireless network interface group and/or a USB interface group;

the first wireless network interface group, the second wireless network interface group, the third wireless network interface group and the USB interface group are all used for sending the data message formed by splitting to a designated server.

2. The high reliability router of claim 1, wherein the first set of wireless network interfaces includes one or more wifi wireless interface modules formed of one or more wifi chips.

3. The high reliability router of claim 1, wherein the second set of wireless network interfaces comprises one or more 4G wireless interface modules formed of one or more 4G modules.

4. The high reliability router of claim 1, wherein the third set of wireless network interfaces comprises one or more WLAN wireless interface modes formed by one or more WLAN modules.

5. The high reliability router of claim 1, wherein the set of USB interfaces comprises one or more USB interfaces.

6. The fusion method of the high-reliability router is characterized by comprising the following steps of:

the high-reliability router continuously detects the network conditions of wireless cells and wired broadband, and obtains the network operation conditions of the wireless cells and the wired broadband;

splitting a request of connecting a terminal with equipment to form a plurality of data messages by a network data packet, and transmitting the plurality of data messages to a designated server by an evaluated network; wherein, each data message corresponds to a path of network node, each path of cellular 4G USB Dongle of the network node which is a multipath aggregation router is a node, and a wired broadband is a node;

after the designated server receives the data message, the data message is spliced and restored to form a complete network data packet;

and forwarding the complete network data packet to a destination server.

7. The method of merging highly reliable routers according to claim 6, wherein the highly reliable routers continuously detect network conditions of wireless cells and wired broadband, and obtain network operation conditions of the wireless cells and wired broadband, comprising:

the high-reliability router continuously detects network conditions of wireless cells and wired broadband and obtains operation parameters of the wireless cells and the wired broadband;

the high-reliability router obtains the network operation conditions of the wireless cellular and the wired broadband by utilizing the operation parameters of the wireless cellular and the wired broadband in combination with a network evaluation model;

the network evaluation model comprises a wireless cellular operation evaluation model and a wired broadband operation evaluation model;

wherein the wireless cellular operation assessment model is as follows:

Q ₀₁ ＝w ₁ ·Q ₁₁ +w ₂ ·Q ₁₂ +w ₃ ·Q ₁₃ +w ₄ ·Q ₁₄

Q ₁₂ ＝(Q ₁₁ -N _p )·[(Q _11max -N _pmax )·B _r ] ^-1

Q ₁₃ ＝(1-E _r )·100％

wherein Q is ₀₁ Network operation evaluation parameters representing a wireless cell between a terminal and a device; q (Q) ₁₁ Representing signal strength evaluation parameters; q (Q) ₁₂ Representing a signal quality evaluation parameter; q (Q) ₁₃ Representing a frequency band quality evaluation parameter; q (Q) ₁₄ Representing data transmission rate evaluation parameters; w (w) ₁ 、w ₂ 、w ₃ And w ₄ Respectively representing weights corresponding to the signal strength evaluation parameter, the signal quality evaluation parameter, the frequency band quality evaluation parameter and the data transmission rate evaluation parameter; n represents the number of interference sources; l (L) _i Representing the interference strength of the ith interference source to the device；D _i Representing a linear distance between an ith interference source and the device; w (W) _0i Representing the weight corresponding to the ith interference source; p represents the actual signal power of the signal received by the device; p (P) ₀ Representing a preset signal power threshold; a represents the signal reception sensitivity of the device; u represents the number of barriers between the terminal and the equipment; d (D) _ui Representing a linear distance between an ith obstacle and the device; h _i Representing the height of the ith obstacle; h ₀ Representing that the height of the obstacle reaches the height corresponding to the minimum of signal space propagation interference; n (N) _p Representing a noise level in an environment in which the device is located; q (Q) _11max Representing the maximum value of signal intensity that occurs until the current evaluation; n (N) _pmax Representing the highest value of noise level in the environment in which the device is located; b (B) _r Representing the ratio between signal and noise; e (E) _r Representing a bit error rate; q (Q) ₄₀ Representing a preset rate evaluation reference index value; r is R ₀ Representing a preset channel data transmission rate threshold; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; r is R _min Representing an actual data transmission rate minimum of a channel between the device and the terminal; s represents the number of channels between the device and the terminal;

the wired broadband operation evaluation model is as follows:

wherein Q is ₀₂ Network operation evaluation parameters representing a wired broadband between the terminal and the device; v (V) _x 、V _s And V _l Respectively representing the data downloading rate, the data uploading rate and the network connection rate of the terminal; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; q (Q) ₂ Representing a preset network operation evaluation parameter reference value of the wired broadband; p (P) _a Indicating the probability of successful data connection between the terminal and the device.

8. The method of merging highly reliable routers according to claim 6, wherein the step of splitting the network packet into a plurality of data packets according to a request from the terminal connection device includes:

receiving a connection request sent by the terminal connection equipment in real time, wherein the connection request comprises network resources required by the terminal connection equipment;

and determining the splitting quantity of the network data packet split into a plurality of data messages currently by combining the connection request sent by the terminal connection equipment and the network resource parameter corresponding to each network node through the unpacking quantity setting model.

9. The method of merging highly reliable routers according to claim 8, wherein the unpacking number setting model is as follows:

wherein M represents the split number of the data message; k (K) _m Representing the total number of network nodes; c represents the data volume of the network data packet; p (P) _a The probability of successful data connection between the terminal and the equipment is represented; v (V) _x0 、V _s0 And V _l0 Respectively representing the average data downloading rate, the average data uploading rate and the average network connection rate of the terminal and the corresponding equipment; r is R _i Representing the actual data transmission rate of the ith channel between the device and the terminal; s denotes the number of channels between the device and the terminal.

10. An apparatus having a high reliability router, wherein the apparatus comprises a user terminal, a high reliability router, an ADSL device, a router, and a cloud server; the user terminal is in data connection with the high-reliability router; the high-reliability router is respectively connected with the ADSL device and the cloud server in a data mode; the ADSL device is in data connection with the router; the router is in data connection with the cloud server; the high reliability router employs the high reliability router of any one of claims 1 to 5.