CN210958413U - Probe monitoring device and IPv4/IPv6 translation equipment with same - Google Patents

Abstract

The application discloses probe monitoring device and IPv4/IPv6 translation equipment with the same, the probe monitoring device comprises a data connection module, a quality monitoring module and a power supply module, wherein the data connection module is configured to be connected with communication data between the quality monitoring module and the IPv4/IPv6 translation equipment, the quality monitoring module is configured to be communicated with the IPv4/IPv6 translation equipment through the data connection module and detect service quality of service provided by the IPv4/IPv6 translation equipment to obtain detection data, and the power supply module is configured to receive an electric signal of a power supply and supply power to the quality monitoring module, the data connection module and the wireless connection module. The probe detection device of the embodiment of the disclosure can detect the service quality provided by the IPv4/IPv6 translation equipment in real time, and meanwhile, a WIFI module is provided for an administrator to quickly acquire real-time detection data.

Description

Probe monitoring device and IPv4/IPv6 translation equipment with same

Technical Field

The disclosure relates to the technical field of internet, in particular to a probe monitoring device and IPv4/IPv6 translation equipment with the same.

Background

The IPv4/IPv6 translation device is a network device which realizes the IPv4/IPv6 translation technology. The IPv4/IPv6 translation technology is applicable to communication between an IPv4 network/node and an IPv6 network/node, and can be classified into two types, namely stateless translation technology (stateful translation) and stateful translation technology (stateful translation). The stateful translation refers to that a mapping relationship between an IPv4 address and an IPv6 address needs to be dynamically generated and maintained in a translation device, whereas a mapping relationship between an IPv4 address and an IPv6 address needs to be maintained through a preset algorithm, which is called stateless translation. The internet standards related to the IPv4/IPv6 translation technology comprise RFC3089, RFC3142, RFC6052, RFC6144, RFC6145, RFC6146, RFC6147, RFC6219, RFC6877, RFC7599 and RFC 7915. The network device meeting one or more of the standards is an IPv4/IPv6 translation device.

The connectivity of the IPv4/IPv6 translation device is monitored by a network management system, which is also a common technical implementation of network devices. However, it is difficult to check whether the traffic passing through the IPv4/IPv6 translation device is normal, and detect whether the IPv4/IPv6 translation device provides a quality guaranteed service for the user in real time. Since the IPv4/IPv6 translation device is a route middleware device, it is not practical to directly monitor the end-to-end service quality on the IPv4/IPv6 translation device. If a user needs to find out a machine for real-time monitoring, the user is difficult in aspects of cost, operation and the like.

Other network devices typically use a network management system to monitor the device, and the relevant open source software includes zabbix, cacti, nagios, and the like. But these open source software only monitor the device itself. At present, no scheme for monitoring the service quality of the IPv4/IPv6 translation equipment in real time exists.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present disclosure provides a probe monitoring apparatus for IPv4/IPv6 translation equipment, including a data connection module, a quality monitoring module, and a power supply module;

the first input/output end of the data connection module is suitable for being electrically connected with the IPv4/IPv6 translation equipment;

the second input and output end of the data connection module is electrically connected with the quality monitoring module;

a first input/output end of the quality monitoring module is electrically connected with a second input/output end of the data connection module;

the power supply input end of the quality monitoring module is electrically connected with the output end of the power supply module;

a first power supply output end of the quality monitoring module is electrically connected with a power supply input end of the data connection module;

the data connection module is configured to perform data communication between the quality monitoring module and the IPv4/IPv6 translation device;

the quality monitoring module is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module, and perform service quality detection on the service provided by the IPv4/IPv6 translation device to obtain detection data;

the power supply module is configured to receive an electric signal of a power supply, supply power to the quality monitoring module, and supply power to the data connection module through the quality monitoring module.

In one possible implementation, the data connection module includes a port physical layer unit, a signal conversion unit, and an RJ45 port;

a first input/output end of the port physical layer unit is used as a second input/output end of the data connection module and is electrically connected with the quality monitoring module;

the second input/output end of the port physical layer unit is electrically connected with the first input/output end of the signal conversion unit;

the second input and output end of the signal conversion unit is electrically connected with the first input and output end of the RJ45 network port;

a second input/output end of the RJ45 network port is used as a first input/output end of the data connection module and is suitable for being electrically connected with a USB interface of the IPv4/IPv6 translation equipment;

the port physical layer unit is configured to convert the physical electrical signal received from the signal conversion unit into encoded data and input the encoded data to the quality monitoring module, and convert the encoded data received from the quality monitoring module into the physical electrical signal and output the physical electrical signal to the signal conversion unit;

the signal conversion unit is configured to receive the physical electrical signal of the port physical layer unit, amplify the physical electrical signal and transmit the amplified physical electrical signal to the RJ45 interface, and receive the physical electrical signal transmitted by the RJ45 interface and transmit the amplified physical electrical signal to the port physical layer;

the RJ45 network port is configured to receive the physical electric signal of the signal conversion unit and send the physical electric signal to the IPv4/IPv6 translation device through a USB-RJ45 line, and receive the physical electric signal sent by the IPv4/IPv6 translation device through the USB-RJ45 line and send the physical electric signal to the signal conversion unit.

In one possible implementation, the quality monitoring module is an ESP32 module.

In a possible implementation manner, the system further comprises a wireless connection module;

a second input/output end of the quality monitoring module is electrically connected with an input/output end of the wireless connection module;

the wireless connection module is suitable for being in wireless connection with the management terminal;

a second power supply output end of the quality monitoring module is electrically connected with a power supply input end of the wireless connection module;

the wireless connection module is configured to acquire the detection data of the quality monitoring module to the management terminal.

In one possible implementation, the power supply module includes a DCDC converter and a power interface;

the output end of the DCDC converter is used as the output end of the power supply module and is electrically connected with the power supply input end of the quality monitoring module;

the input end of the DCDC converter is electrically connected with the output end of the power interface;

the DCDC converter is configured to stably output the electric signal received through the power interface to the quality monitoring module;

the power interface is configured to receive an electrical signal of a power input and output the electrical signal to the DCDC converter.

In one possible implementation, the port physical layer unit is an IP101GRI chip.

In one possible implementation, the DCDC converter is of the type MT3012 NSBR.

In a possible implementation manner, the device further comprises an indicator light module;

the input end of the indicator light module is electrically connected with the output end of the quality monitoring module;

the output end of the indicator light module is suitable for being electrically connected with an LED indicator light of a mainboard of the IPv4/IPv6 translation equipment;

the indicator light module is configured to receive the signal of the quality monitoring module and send a detection state signal to the LED indicator light of the IPv4/IPv6 translating equipment.

In a possible implementation manner, the indicator light module is a TTL serial port.

According to another aspect of the present disclosure, there is also provided an IPv4/IPv6 translation apparatus, comprising the probe monitoring device described in any one of the preceding paragraphs;

the probe monitoring device is electrically connected with a data transmission interface of the IPv4/IPv6 translation equipment through a data connecting line;

the probe monitoring device and the IPv4/IPv6 translation device share one power supply;

and the indicator light module of the probe monitoring equipment is electrically connected with the indicator light of the mainboard of the IPv4/IPv6 translation equipment.

By connecting the probe monitoring device of the embodiment of the disclosure to an IPv4/IPv6 translation device, wherein the probe monitoring device includes a data connection module, a quality monitoring module and a power supply module, wherein a first input/output end of the data connection module is adapted to be electrically connected to an IPv4/IPv6 translation device, a second input/output end of the data connection module is electrically connected to the quality monitoring module, a first input/output end of the quality monitoring module is electrically connected to a second input/output end of the data connection module, a power supply input end of the quality monitoring module is electrically connected to an output end of the power supply module, a first power output end of the quality monitoring module is electrically connected to a power supply input end of the data connection module, a second power output end of the quality monitoring module is electrically connected to a power supply input end of the wireless connection module, the data connection module is configured to perform data communication between the quality monitoring module and the IPv4/IPv 36, the quality monitoring module is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module and perform service quality detection on the service provided by the IPv4/IPv6 translation device to obtain detection data, and the power supply module is configured to receive an electric signal of a power supply, supply power to the quality monitoring module and supply power to the data connection module and the wireless connection module through the quality monitoring module. The probe detection device of the embodiment of the disclosure can detect the service quality provided by the IPv4/IPv6 translation equipment in real time.

Other features and aspects of the present disclosure will become apparent from the following detailed description of exemplary embodiments, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments, features, and aspects of the disclosure and, together with the description, serve to explain the principles of the disclosure.

FIG. 1 shows a block diagram of a probe monitoring device of an embodiment of the present disclosure;

FIG. 2 shows a schematic diagram of an IPv4/IPv6 translation device of an embodiment of the disclosure.

Detailed Description

Various exemplary embodiments, features and aspects of the present disclosure will be described in detail below with reference to the accompanying drawings. In the drawings, like reference numbers can indicate functionally identical or similar elements. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The word "exemplary" is used exclusively herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments.

Furthermore, in the following detailed description, numerous specific details are set forth in order to provide a better understanding of the present disclosure. It will be understood by those skilled in the art that the present disclosure may be practiced without some of these specific details. In some instances, methods, means, elements and circuits that are well known to those skilled in the art have not been described in detail so as not to obscure the present disclosure.

Fig. 1 shows a block diagram of a probe monitoring device 100 according to an embodiment of the present disclosure. As shown in fig. 1, the probe monitoring apparatus 100 includes:

a data connection module 110, a quality monitoring module 120, a wireless connection module 130 and a power supply module 140, wherein a first input/output end of the data connection module 110 is adapted to be electrically connected to an IPv4/IPv6 translation device, a second input/output end of the data connection module 110 is electrically connected to the quality monitoring module 120, a first input/output end of the quality monitoring module 120 is electrically connected to a second input/output end of the data connection module 110, a second input/output end of the quality monitoring module 120 is electrically connected to an input/output end of the wireless connection module 130, the wireless connection module 130 is adapted to be wirelessly connected to a management end, a power supply input end of the quality monitoring module 120 is electrically connected to an output end of the power supply module 140, a first power supply output end of the quality monitoring module 120 is electrically connected to a power supply input end of the data connection module 110, a second power supply output end of the quality monitoring module, the data connection module 110 is configured to perform data communication between the quality monitoring module 120 and the IPv4/IPv6 translation device, the quality monitoring module 120 is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module 110, perform service quality detection on a service provided by the IPv4/IPv6 translation device to obtain detection data, and send the detection data to the wireless connection module 130, the wireless connection module 130 is configured to obtain the detection data sent by the quality monitoring module 120 to a management terminal, and the power supply module 140 is configured to receive an electric signal of a power supply, supply power to the quality monitoring module 120, and supply power to the data connection module 110 and the wireless connection module 130 through the quality monitoring module 120.

It should be noted that the probe monitoring device 100 of the embodiment of the present disclosure is used in an IPv4/IPv6 translation device, where the IPv4/IPv6 translation device includes a stateless translation device and a stateful translation device.

By connecting the probe monitoring device 100 of the embodiment of the present disclosure to an IPv4/IPv6 translation device, wherein the probe monitoring device 100 includes a data connection module 110, a quality monitoring module 120, a wireless connection module 130, and a power supply module 140, wherein a first input/output terminal of the data connection module 110 is adapted to be electrically connected to the IPv4/IPv6 translation device, a second input/output terminal of the data connection module 110 is electrically connected to the quality monitoring module 120, a first input/output terminal of the quality monitoring module 120 is electrically connected to a second input/output terminal of the data connection module 110, a power supply input terminal of the quality monitoring module 120 is electrically connected to an output terminal of the power supply module 140, a first power supply output terminal of the quality monitoring module 120 is electrically connected to a power supply input terminal of the data connection module 110, the data connection module 110 is configured to perform data communication between the quality monitoring module 120 and the IPv4/IPv6 translation device, the quality monitoring module 120 is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module 110 and perform service quality detection on the service provided by the IPv4/IPv6 translation device to obtain detection data, and the power supply module 140 is configured to receive an electrical signal of a power supply, supply power to the quality monitoring module 120, and supply power to the data connection module 110 and the wireless connection module 130 through the quality monitoring module 120. The probe detection device of the embodiment of the disclosure can detect the service quality provided by the IPv4/IPv6 translation equipment in real time, and meanwhile, a WIFI module is provided for an administrator to quickly acquire real-time detection data.

Specifically, referring to fig. 1, the data connection module 110 includes a port physical layer unit, a signal conversion unit and an RJ45 network port, and the data connection module 110 is configured to connect the quality monitoring module 120 and the IPv4/IPv6 translation device to communicate data therebetween.

In a possible implementation manner, referring to fig. 1, the port physical layer unit may use a PHY (port physical layer) chip with a model of IP101GRI, the isolation transformer is a transform device (isolation transformer), in terms of connection manner, a first input/output end of the IP101GRI chip is electrically connected to the quality monitoring module 120 as a second input/output end of the data connection module 110, a second input/output end of the IP101GRI chip is electrically connected to a first input/output end of the isolation transformer, a second input/output end of the isolation transformer is electrically connected to a first input/output end of the RJ45 network port, and a second input/output end of the RJ45 network port is adapted to be electrically connected to a USB interface of the IPv4/IPv6 translation device as a first input/output end of the data connection module 110. Functionally, the IP101GRI chip converts a physical electrical signal received from the isolation transformer into encoded data, inputs the encoded data to the quality monitoring module 120, and converts the encoded data received from the quality monitoring module 120 into a physical electrical signal, and outputs the physical electrical signal to the isolation transformer, the isolation transformer is configured to receive the physical electrical signal of the IP101GRI chip, amplify the physical electrical signal, send the physical electrical signal to the RJ45 interface, receive the electrical signal sent by the RJ45 interface, and send the electrical signal to the port physical layer, and the RJ45 network port is configured to receive the physical electrical signal of the isolation transformer, send the physical electrical signal to the IPv4/IPv6 translation device through the USB-RJ45 line, and simultaneously receive the physical electrical signal sent by the IPv4/IPv6 translation device through the USB-RJ. So that the quality monitoring module 120 communicates with IPv4/IPv6 translation devices.

It should be noted that the data connection module is not limited to a connection mode from an RJ45 network port to a USB interface, but also includes a connection mode of a serial port, and the purpose of data connection between the IPv4/IPv6 translation device and the probe monitoring apparatus 100 according to the embodiment of the present disclosure can be achieved.

Further, referring to fig. 1, a first input/output terminal of the quality monitoring module 120 is electrically connected to a second input/output terminal of the data connection module 110, a second input/output terminal of the quality monitoring module 120 is electrically connected to an input/output terminal of the wireless connection module 130, a power supply input terminal of the quality monitoring module 120 is electrically connected to an output terminal of the power supply module 140, and the quality monitoring module 120 is configured to communicate with the IPv4/IPv6 translation device through the data connection module 110, perform service quality detection on a service provided by the IPv4/IPv6 translation device, obtain detection data, and send the detection data to the wireless connection module 130.

In one possible implementation, the quality monitoring module 120 is an ESP32 chip. The first input and output end of the ESP32 chip is electrically connected to the second input and output end of the data connection module 110, the second input and output end of the ESP32 chip is electrically connected to the input and output end of the wireless connection module 130, the power supply input end of the ESP32 chip is electrically connected to the output end of the power supply module 140, and the ESP32 chip is configured to communicate with the IPv4/IPv6 translation device through the data connection module 110, detect the service quality of the service provided by the IPv4/IPv6 translation device to obtain detection data, and send the detection data to the wireless connection module 130. The ESP32 chip is connected with the ATX main board of the IPv4/IPv6 translation equipment through a network port of RJ45 through a USB-RJ45 adapter. The two parties configure a default internet private IPv4 address, and can normally communicate. Therefore, the quality monitoring module 120 can simulate a client, connect to the corresponding server through the uplink network access of the IPv4/IPv6 translation device, and periodically detect the corresponding service quality.

It should be noted that the chip used by the quality monitoring module 120 is not limited to the ESP32 module, and may achieve the required functions.

Further, referring to fig. 1, the probe monitoring apparatus 100 according to the embodiment of the disclosure may further include a wireless connection module 130, an input/output end of the wireless connection module 130 is electrically connected to a second input/output end of the quality monitoring module 120, and the wireless connection module 130 is configured to obtain the detection data of the quality monitoring module 120 so that the management end obtains the detection data.

In one possible implementation, the wireless connection Module 130 is a WIFI Module (WIFI Module). The input/output end of the WIFI module is electrically connected to the second input/output end of the quality monitoring module 120, and the WIFI module is configured to acquire the detection data of the quality monitoring module 120, so that the management end acquires the detection data. When the WIFI module works, a worker can use the control end to connect a WIFI signal sent by the WIFI module, monitoring data can be acquired from the quality monitoring module 120 in a WIFI connection mode, and the worker can check the service quality provided by the IPv4/IPv6 translation equipment in real time.

Further, referring to fig. 1, a power supply input terminal of the quality monitoring module 120 is electrically connected to an output terminal of the power supply module 140, a first power output terminal of the quality monitoring module 120 is electrically connected to a power input terminal of the data connection module 110, a second power output terminal of the quality monitoring module 120 is electrically connected to a power input terminal of the wireless connection module 130, and the power supply module 140 is configured to receive an electrical signal of a power supply, supply power to the quality monitoring module 120, and supply power to the data connection module 110 and the wireless connection module 130 through the quality monitoring module 120.

In one possible implementation, the power supply module 140 includes a DCDC converter (DCDC BUCK) and a power interface, and preferably, the model of the DCDC converter is MT3012NSBR, and the power interface is a direct current power interface (DC Input). An output terminal of the DCDC converter is electrically connected to a power supply input terminal of the quality monitoring module 120 as an output terminal of the power supply module 140, an input terminal of the DCDC converter is electrically connected to an output terminal of the power interface, the DCDC converter is configured to stably output an electrical signal received through the power interface to the quality monitoring module 120, and the power interface is configured to receive an electrical signal input by a power supply and output the electrical signal to the DCDC converter. In addition, the wireless connection module 130 and the data connection module 110 are indirectly connected to the Power supply module 140, the first Power output end of the quality monitoring module 120 is electrically connected to the Power input end of the data connection module 110, the second Power output end of the quality monitoring module 120 is electrically connected to the Power input end of the wireless connection module 130, so as to supply Power to the wireless connection module 130 and the data connection module 110, and thus, an external Power source (Power) is connected through a Power interface, and a received electrical signal is output to the DCDC converter, so that the DCDC converter stably supplies Power to the quality monitoring module 120, the data connection module 110 and the WiFi module.

Further, referring to fig. 1, the probe monitoring apparatus 100 of the embodiment of the disclosure further includes an indicator light module, wherein an input end of the indicator light module is electrically connected to an output end of the quality monitoring module 120, an output end of the indicator light module is adapted to be electrically connected to an LED indicator light of an IPv4/IPv6 translation device, and the indicator light module is configured to receive a signal of the quality monitoring module 120 and send a detection status signal to the LED indicator light of the IPv4/IPv6 translation device.

In a possible implementation manner, the indicator lamp module is a TTL serial port (TTL pin), an input end of the TTL serial port is electrically connected with an output end of the quality monitoring module 120, an output end of the TTL serial port is adapted to be electrically connected with an LED indicator lamp of the IPv4/IPv6 translation device, the TTL serial port is electrically connected with an output end of the quality monitoring module 120 to control a signal indicator lamp state of the IPv4/IPv6 translation device, so as to achieve the purpose of visually checking a working state of the probe monitoring device 100, and improve working efficiency.

It should be noted that, although the probe detection device is described above by taking the above-described embodiment as an example, those skilled in the art will understand that the present disclosure should not be limited thereto. In fact, the user can flexibly set the probe detection device according to personal preference and/or practical application scenes as long as the required functions are achieved.

Thus, by accessing the probe monitoring apparatus 100 of the embodiment of the present disclosure into an IPv4/IPv6 translation device, wherein the probe monitoring apparatus 100 includes a data connection module 110, a quality monitoring module 120, a wireless connection module 130 and a power supply module 140, wherein a first input/output terminal of the data connection module 110 is adapted to be electrically connected to the IPv4/IPv6 translation device, a second input/output terminal of the data connection module 110 is electrically connected to the quality monitoring module 120, a first input/output terminal of the quality monitoring module 120 is electrically connected to a second input/output terminal of the data connection module 110, a power supply input terminal of the quality monitoring module 120 is electrically connected to an output terminal of the power supply module 140, a first power supply output terminal of the quality monitoring module 120 is electrically connected to a power supply input terminal of the data connection module 110, the data connection module 110 is configured to perform data communication between the quality monitoring module 120 and the IPv4/IPv6 translation device, the quality monitoring module 120 is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module 110 and perform service quality detection on the service provided by the IPv4/IPv6 translation device to obtain detection data, and the power supply module 140 is configured to receive an electrical signal of a power supply, supply power to the quality monitoring module 120, and supply power to the data connection module 110 and the wireless connection module 130 through the quality monitoring module 120. The probe detection device of the embodiment of the disclosure can detect the service quality provided by the IPv4/IPv6 translation equipment in real time, and meanwhile, a WIFI module is provided for an administrator to quickly acquire real-time detection data.

In addition, referring to fig. 2, based on any one of the probe monitoring devices 100 described above, the present disclosure also provides an IPv4/IPv6 translation device, and the IPv4/IPv6 translation device includes a stateless translation device and a stateful translation device. The IPv4/IPv6 translation device provided by the present disclosure includes the probe monitoring apparatus 100 described in any one of the preceding paragraphs. The probe monitoring device 100 is installed in a case of an IPv4/IPv6 translation device, the probe monitoring device is electrically connected with a USB interface of the IPv4/IPv6 translation device through a USB-RJ45 line, the probe monitoring device and the IPv4/IPv6 translation device share one power supply, and an indicator light module of the probe monitoring device is electrically connected with an indicator light of a mainboard of the IPv4/IPv6 translation device. The monitoring device is used for monitoring the service quality condition provided by IPv4/IPv6 translation equipment at regular time, and enabling managers to check the service condition of the IPv4/IPv6 translation equipment in real time through WIFI signals, and can also check the working state of the probe monitoring device 100 through a main board LED indicator lamp of the IPv4/IPv6 translation equipment, and the probe monitoring device 100 is installed in the IPv4/IPv6 translation equipment, so that the IPv4/IPv6 translation equipment can monitor the service quality in real time.

Having described embodiments of the present disclosure, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (10)

1. A probe monitoring device is used for IPv4/IPv6 translation equipment and is characterized by comprising a data connection module, a quality monitoring module and a power supply module;

the first input/output end of the data connection module is suitable for being electrically connected with the IPv4/IPv6 translation equipment;

the second input and output end of the data connection module is electrically connected with the quality monitoring module;

a first input/output end of the quality monitoring module is electrically connected with a second input/output end of the data connection module;

the power supply input end of the quality monitoring module is electrically connected with the output end of the power supply module;

a first power supply output end of the quality monitoring module is electrically connected with a power supply input end of the data connection module;

the data connection module is configured to perform data communication between the quality monitoring module and the IPv4/IPv6 translation device;

the quality monitoring module is configured to perform data communication with the IPv4/IPv6 translation device through the data connection module, and perform service quality detection on the service provided by the IPv4/IPv6 translation device to obtain detection data;

the power supply module is configured to receive an electric signal of a power supply, supply power to the quality monitoring module, and supply power to the data connection module through the quality monitoring module.

2. The probe monitoring device of claim 1, wherein the data connection module comprises a port physical layer unit, a signal conversion unit, and an RJ45 port;

a first input/output end of the port physical layer unit is used as a second input/output end of the data connection module and is electrically connected with the quality monitoring module;

the second input/output end of the port physical layer unit is electrically connected with the first input/output end of the signal conversion unit;

the second input and output end of the signal conversion unit is electrically connected with the first input and output end of the RJ45 network port;

a second input/output end of the RJ45 network port is used as a first input/output end of the data connection module and is suitable for being electrically connected with a USB interface of the IPv4/IPv6 translation equipment;

the port physical layer unit is configured to convert the physical electrical signal received from the signal conversion unit into encoded data and input the encoded data to the quality monitoring module, and convert the encoded data received from the quality monitoring module into the physical electrical signal and output the physical electrical signal to the signal conversion unit;

the signal conversion unit is configured to receive the physical electrical signal of the port physical layer unit, amplify the physical electrical signal and transmit the amplified physical electrical signal to the RJ45 interface, and receive the physical electrical signal transmitted by the RJ45 interface and transmit the amplified physical electrical signal to the port physical layer;

the RJ45 network port is configured to receive the physical electric signal of the signal conversion unit and send the physical electric signal to the IPv4/IPv6 translation device through a USB-RJ45 line, and receive the physical electric signal sent by the IPv4/IPv6 translation device through the USB-RJ45 line and send the physical electric signal to the signal conversion unit.

3. The probe monitoring device of claim 1, wherein the quality monitoring module is an ESP32 module.

4. The probe monitoring device of claim 1, further comprising a wireless connection module;

a second input/output end of the quality monitoring module is electrically connected with an input/output end of the wireless connection module;

the wireless connection module is suitable for being in wireless connection with the management terminal;

a second power supply output end of the quality monitoring module is electrically connected with a power supply input end of the wireless connection module;

the wireless connection module is configured to acquire the detection data of the quality monitoring module to the management terminal.

5. The probe monitoring device of claim 1, wherein the power module comprises a DCDC converter and a power interface;

the output end of the DCDC converter is used as the output end of the power supply module and is electrically connected with the power supply input end of the quality monitoring module;

the input end of the DCDC converter is electrically connected with the output end of the power interface;

the DCDC converter is configured to stably output the electric signal received through the power interface to the quality monitoring module;

the power interface is configured to receive an electrical signal of a power input and output the electrical signal to the DCDC converter.

6. The probe monitoring device of claim 2, wherein the port physical layer unit is an IP101GRI chip.

7. The probe monitoring device of claim 5, wherein the DCDC converter is of type MT3012 NSBR.

8. The probe monitoring device of claim 1, further comprising an indicator light module;

the input end of the indicator light module is electrically connected with the output end of the quality monitoring module;

the output end of the indicator light module is suitable for being electrically connected with an LED indicator light of a mainboard of the IPv4/IPv6 translation equipment;

the indicator light module is configured to receive the signal of the quality monitoring module and send a detection state signal to the LED indicator light of the IPv4/IPv6 translating equipment.

9. The probe monitoring device of claim 8, wherein the indicator light module is a TTL serial port.

10. An IPv4/IPv6 translation apparatus comprising the probe monitoring device of any one of claims 1 to 9;

the probe monitoring device is electrically connected with a data transmission interface of the IPv4/IPv6 translation equipment through a data connecting line;

the probe monitoring device and the IPv4/IPv6 translation device share one power supply;

and the indicator light module of the probe monitoring equipment is electrically connected with the indicator light of the mainboard of the IPv4/IPv6 translation equipment.

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