CN116938601B

CN116938601B - Division authentication method for real-name authentication equipment

Info

Publication number: CN116938601B
Application number: CN202311188377.XA
Authority: CN
Inventors: 夏东
Original assignee: Hunan Vision Miracle Intelligent Technology Co ltd
Current assignee: Hunan Vision Miracle Intelligent Technology Co ltd
Priority date: 2023-09-15
Filing date: 2023-09-15
Publication date: 2023-11-24
Anticipated expiration: 2043-09-15
Also published as: CN116938601A

Abstract

The application provides a division authentication method for real-name authentication equipment, S1, a head station device carries out network speed measurement according to a list sequence of equipment to select group leader equipment; s2, marking a sequence obtained by removing equipment of the group leader from the equipment list sequence as a first equipment list sequence; taking group leader equipment as a group leader, carrying out network speed measurement on the first equipment list sequence, and selecting subordinate equipment; a group network is formed by group leader equipment and subordinate equipment; s3, sending the personnel information table to a head station device, sending the personnel information table to a group leader device by the head station device, dividing the personnel information table into first personnel information and second personnel information by the group leader device, reserving the first personnel information by the group leader device, and sending the second personnel information to subordinate devices in the group; s4, when the unknown data appears in the authentication, sending an authentication data packet of the unknown data to the group members in the group, and carrying out concurrent authentication; and if the authentication of the devices in the group is successful, returning a personnel information data packet to finish the authentication.

Description

Division authentication method for real-name authentication equipment

Technical Field

The application relates to the technical field of authentication equipment, in particular to a division authentication method for real-name authentication equipment.

Background

The real-name system equipment is special face attendance equipment, realizes attendance checking of workers on the basis of realizing the real-name system of labor workers, distributes by labor, and contributes to social stability. The facial features of people are taken as one of personal important information, the safety of the facial features is focused, in the labor industry real-name system platform, the serial number of the equipment and the platform are bound, and people are bound with the equipment, so that the situation of information leakage caused by equipment stealing can be effectively prevented. The traditional real-name authentication method generally adopts a plurality of devices to carry out authentication, the upper network sends all personnel information to each authentication device, and each device carries out independent authentication.

However, the conventional authentication method cannot guarantee the security of personnel data, for example, when a single device containing personnel information is lost or invaded, the personnel information is no longer secure; in addition, the traditional authentication method needs to send complete personnel information to each piece of equipment, and when the data volume is large, the authentication speed is slow and the authentication speed is blocked due to the problems of network delay and the like.

Disclosure of Invention

The application provides a division authentication method for real-name authentication equipment, which is used for solving the technical problems that the traditional authentication method cannot ensure personnel information safety and the authentication speed is slow because of a data transmission mode.

In order to achieve the above purpose, the present application provides a separate authentication method for real-name authentication devices, which is used for a system formed by communication connection of more than two real-name authentication devices and a cluster server, wherein the cluster server comprises a database storage unit and a device management module which are connected with each other, and the database storage unit comprises a device list sequence and a personnel information table; the method comprises the following steps:

s1, transmitting the equipment list sequence to first equipment in the equipment list sequence through an equipment management module, and carrying out network speed measurement by the first equipment according to the equipment list sequence to select group leader equipment.

S2, marking a sequence obtained by removing equipment of the group leader from the equipment list sequence as a first equipment list sequence; taking group leader equipment as a group leader, carrying out network speed measurement on the first equipment list sequence, and selecting lower equipment for the group leader equipment; the group network is composed of group leader devices and subordinate devices.

S3, sending the personnel information list to the first equipment through the equipment management module, sending the received personnel information list to all group leader equipment by the first equipment, dividing the personnel information list into first personnel information and second personnel information by the group leader equipment, reserving the first personnel information by the group leader equipment, and sending the second personnel information to subordinate equipment in a group network.

S4, authenticating through a real-name authentication device, and when unknown data appear in the device, sending authentication data packets of the unknown data to all panelists in the group to perform concurrent authentication; and if the authentication of the devices in the group is successful, returning a personnel information data packet to finish the authentication.

Preferably, in S1, when selecting a group leader device, the method includes:

and selecting the first N-bit network speed arrangement devices, wherein N is a positive integer, and taking the first device and the first N-bit network speed arrangement devices as group leader devices.

Preferably, in S3, when the personnel information table is divided into the first personnel information and the second personnel information, the personnel information table is first divided into a parts, a is the number of all devices in the group network, and a is a positive integer; each part of the equally divided personnel information list is recorded as 1 part of sub personnel information list; the first personnel information comprises a 1-part personnel information table; the second personnel information comprises an A-1 part personnel information list; and when the second personnel information is sent to the subordinate devices in the group network, 1 part of sub personnel information list is sent to each subordinate device.

Preferably, in S1, when the first device loops network speed measurement for all devices in the device list sequence:

sending a random content data packet with preset data quantity to another piece of equipment, and after receiving the data, the other piece of equipment returns a result of providing the MD5 feature code of the piece of data to the first piece of equipment, namely sending big data and receiving small data, wherein the speed is measured by an asymmetric network speed; meanwhile, reverse speed measurement calculation, namely asymmetric data transmission is performed; and sequencing the time of the first equipment and all subsequent equipment for completing the two-time speed measurement to obtain the network speed sequencing.

Preferably, in S2, when the group leader selects a lower level device, the group leader selects a device with a network speed arranged in the first M bits as the lower level device, M is a positive integer, and the group leader and the lower level device form a group network.

Preferably, in S2, when the group leader device has selected the subordinate device and still has the remaining device, the subordinate device selects the remaining device with the faster network speed as the subordinate device of the same group leader device; and when no equipment remains, the construction of the group network is completed.

Preferably, in S3, the group leader device sends the personnel information to the subordinate devices in the group network in a distributed issuing and separated network occupation manner.

Preferably, in the working process of each device, heartbeat requests are initiated to other devices in the group network every preset time period, and whether the devices are in a specified network is judged; if the heartbeat check fails for a plurality of times, the equipment with the failed heartbeat check is marked as the failed equipment, a locking mechanism is triggered, and members in the group network do not perform concurrent authentication with the failed equipment.

Preferably, in S4, the personnel information packet includes a personnel ID and a name;

if the authentication of the devices in the group fails, the unknown data is not contained in the personnel information table.

The application has the following beneficial effects:

according to the division management method of the real-name authentication equipment, equipment with relatively fast networks among the equipment is selected as group leader equipment through the head equipment, so that the equipment management module sends the personnel information list to the head equipment and then the head equipment can send the personnel information list to all the group leader equipment at the highest speed; the group leader device selects devices faster than the group leader device to form a group network, so that the group leader device can distribute personnel information at the highest speed; when concurrent authentication is performed in the group network, each device only keeps a part of personnel information, so that the split authentication method of the scheme reduces the leakage risk of face privacy information; a plurality of small group networks are established, and a small local authentication system is formed between the devices in the groups, so that the labor division authentication method of the scheme reduces the working pressure of the single device, shares the working pressure to the devices in the groups, can improve the authentication efficiency and reduces the working pressure of the single device.

In addition to the objects, features and advantages described above, the present application has other objects, features and advantages. The application will be described in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application. In the drawings:

fig. 1 is a schematic flow chart of a preferred embodiment of the present application.

Detailed Description

Embodiments of the application are described in detail below with reference to the attached drawings, but the application can be implemented in a number of different ways, which are defined and covered by the claims.

Referring to fig. 1, in a preferred embodiment of the present application, a separate authentication method for a real-name authentication device is provided, where the separate authentication method is used in a system formed by connecting more than two real-name authentication devices in communication with a cluster server, where the cluster server includes a database storage unit and a device management module that are connected to each other, and the database storage unit includes a device list sequence and a personnel information table; the method comprises the following steps:

In S1, when selecting a group leader device, it includes:

In S1, when the first device circularly performs network speed measurement on all devices in the device list sequence:

In the preferred embodiment of the application, the equipment with faster network is selected as the group leader equipment by the head equipment, so that the equipment management module can send the personnel information table to all the group leader equipment at the highest speed after the equipment management module sends the personnel information table to the head equipment.

In S2, when the group leader selects a lower level device, the group leader selects a device whose network speed is arranged in the first M bits as the lower level device, M is a positive integer, and a group network is formed by the group leader and the lower level device.

In the preferred embodiment of the application, the equipment with higher network speed between the equipment outside the group leader equipment and the group leader equipment is selected as the subordinate equipment by the group leader equipment, so that the group leader equipment can send information to the subordinate equipment at the highest speed.

In S2, when the group leader device has remained the devices after selecting the lower-level device, the lower-level device selects the device with faster network speed as the lower-level device of the same group leader device; and when no equipment remains, the construction of the group network is completed. I.e. the faster parts of the relative physical network between the devices within each group of networks.

In the preferred embodiment of the application, when the group leader equipment is still left after the lower level equipment is selected, the lower level equipment selects the remaining equipment as the lower level equipment of the same group leader equipment, namely, the lower level equipment of all the same group leader equipment is the same level equipment, so that all the equipment has own group leader equipment, the establishment of a group network is completed and perfected, and the concurrency authentication between the equipment in the group can be realized at the fastest speed.

In S3, the group leader device sends personnel information to subordinate devices in the group network in a distributed issuing and separated network occupation mode.

In the preferred embodiment of the application, when personnel information is issued in the group, a distributed issuing and separated network occupation mode is adopted, so that the system resources of a server are saved, and the bandwidth is reduced.

In S3, when the personnel information table is divided into first personnel information and second personnel information, firstly, the personnel information table is equally divided into A parts, wherein A is the number of all devices in a group network, and A is a positive integer; each part of the equally divided personnel information list is recorded as 1 part of sub personnel information list; the first personnel information comprises a 1-part personnel information table; the second personnel information comprises an A-1 part personnel information list; and when the second personnel information is sent to the subordinate devices in the group network, 1 part of sub personnel information list is sent to each subordinate device.

In S4, the person information packet includes a person ID and a name;

In the preferred embodiment of the application, the concurrent authentication mode is adopted, and when the number of personnel is more, the speed of authentication can be obviously improved through the concurrent authentication among the devices in the preferred group network; and the authentication data packet sent out during concurrent authentication is a big data packet containing information such as face recognition and the like, and the group member returns only a small data packet containing personnel information, so that the authentication speed is further improved by adopting a mode of sending the authentication big data packet and returning the authentication small data packet.

In the preferred embodiment of the application, in the working process of each device, heartbeat requests are initiated to other devices in the group network at intervals of a preset time period, and whether the devices are in a specified network is judged; if the heartbeat check fails for a plurality of times, the equipment with the failed heartbeat check is marked as the failed equipment, a locking mechanism is triggered, and members in the group network do not perform concurrent authentication with the failed equipment.

In the preferred embodiment of the application, whether the equipment is in a normal working state is verified through heartbeat verification, if the equipment cannot meet the condition, the equipment is marked as the failure equipment, and the members in the group cannot perform concurrent authentication on the failure equipment, so that the safety of data is improved.

Claims

1. The separate authentication method for the real-name authentication equipment is used for a system formed by communication connection of more than two real-name authentication equipment and a cluster server, wherein the cluster server comprises a database storage unit and an equipment management module which are connected with each other, and the database storage unit comprises an equipment list sequence and a personnel information table; characterized in that the method comprises the steps of:

s1, transmitting a device list sequence to first equipment in the device list sequence through an equipment management module, and carrying out network speed measurement by the first equipment according to the device list sequence to select group leader equipment;

the method comprises the following steps of: selecting a device with the network speed arranged in the first N bits, wherein N is a positive integer, and taking the head device and the device with the network speed arranged in the first N bits as group leader devices;

s2, marking the sequence of the equipment list sequence after the equipment list sequence is removed from the group leader equipment as a first equipment list sequence; taking the group leader equipment as a group leader, carrying out network speed measurement on the first equipment list sequence, and selecting a lower-level equipment for the group leader equipment; a group network is formed by group leader equipment and subordinate equipment;

s3, sending the personnel information list to a head station device through a device management module, sending the received personnel information list to all group leader devices by the head station device, dividing the personnel information list into first personnel information and second personnel information by the group leader device, reserving the first personnel information by the group leader device, and sending the second personnel information to subordinate devices in a group network;

when the personnel information table is divided into first personnel information and second personnel information, firstly, the personnel information table is averagely divided into A parts, wherein A is the number of all devices in a group network, and A is a positive integer; each part of the equally divided personnel information list is recorded as 1 part of sub personnel information list; the first personnel information comprises 1 part of personnel information list; the second personnel information comprises an A-1 part personnel information list; when the second personnel information is sent to the subordinate devices in the group network, 1 part of sub personnel information list is sent to each subordinate device;

s4, authenticating through a real-name authentication device, and when unknown data appear in the real-name authentication device, sending authentication data packets of the unknown data to all panelists in the group to perform concurrent authentication; and if the authentication of the devices in the group is successful, returning a personnel information data packet to finish the authentication.

2. The split authentication method for a real-name authentication device according to claim 1, wherein in S1, when a network speed measurement is performed on all devices in the device list sequence by a head station device in a circulation manner:

3. The authentication method according to claim 2, wherein in S2, when the group leader selects a lower device, the group leader selects a device whose network speed is arranged in the first M bits as the lower device, M is a positive integer, and the group leader and the lower device form a group network.

4. The authentication method for the real-name authentication device according to claim 3, wherein in S2, when the group leader device has selected the lower-level device and has remained the device, the lower-level device selects the remaining device with the faster network speed as the lower-level device of the same group leader device; and when no equipment remains, the construction of the group network is completed.

5. The authentication method according to claim 4, wherein in S3, the group leader device sends the personnel information to the subordinate devices in the group network in a distributed distribution and separated network occupation manner.

6. The authentication method for real-name authentication equipment according to claim 5, wherein each equipment initiates heartbeat requests to other equipment in the group network every preset time period during the working process, and judges whether the equipment is in a specified network; if the heartbeat check fails for a plurality of times, the equipment with the failed heartbeat check is marked as the failed equipment, a locking mechanism is triggered, and members in the group network do not perform concurrent authentication with the failed equipment.

7. The split authentication method for a real-name authentication apparatus according to claim 6, wherein in S4, the person information packet includes a person ID and a name;

and if the authentication of the devices in the group fails, the unknown data is not contained in the personnel information table.