CN110839263A - Information configuration method, device, equipment and storage medium - Google Patents

Abstract

The embodiment of the invention discloses an information configuration method, an information configuration device, information configuration equipment and a storage medium, wherein the method comprises the following steps: receiving configuration information sent by network equipment; determining a frequency point related to mobility management and/or a cell corresponding to the frequency point according to the configuration information and a network identifier of an operator to which the terminal belongs; measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result; and determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

Description

Information configuration method, device, equipment and storage medium

Technical Field

The embodiment of the invention relates to but is not limited to a 5G communication technology, in particular to an information configuration method, an information configuration device, information configuration equipment and a storage medium.

Background

In the 5G era, frequency points and cells to be measured by the terminal are increased by more than 10 times compared with the 4G era, and if optimization is not performed, the measurement power consumption, measurement evaluation and access delay of the terminal are increased sharply, so that the user experience of the 5G terminal is seriously influenced.

Disclosure of Invention

In view of the above, embodiments of the present invention provide an information configuring method, apparatus, device, and storage medium to solve at least one problem in the related art.

The technical scheme of the embodiment of the invention is realized as follows:

the embodiment of the invention provides an information configuration method, which comprises the following steps:

receiving configuration information sent by network equipment;

determining frequency points related to small mobility management and/or cells corresponding to the frequency points according to the configuration information and the network identifier of an operator to which the terminal belongs;

measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result;

and determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment of the invention provides an information configuration method, which comprises the following steps:

sending configuration information to a terminal, wherein the configuration information comprises at least one of the following:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

An embodiment of the present invention provides an information configuration apparatus, where the apparatus includes:

a first receiving unit, configured to receive configuration information sent by a network device;

a first determining unit, configured to determine a frequency point and/or a cell corresponding to the frequency point related to mobility management according to the configuration information and a network identifier of an operator to which the terminal belongs;

the first measurement unit is used for measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result;

and the second determining unit is used for determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

An embodiment of the present invention provides an information configuration apparatus, where the apparatus includes:

a third determining unit, configured to determine configuration information, where the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises inter-system frequency point information and/or network identification corresponding to the frequency point;

and the sending unit is used for sending the configuration information to the terminal.

An embodiment of the present invention provides a computer device, including a memory and a processor, where the memory stores a computer program executable on the processor, and the processor implements the steps in the method when executing the program.

Embodiments of the present invention provide a computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, implements the steps of the above-mentioned method.

In the embodiment of the invention, configuration information sent by network equipment is received; determining a frequency point related to mobility management and/or a cell corresponding to the frequency point according to the configuration information and a network identifier of an operator to which the terminal belongs; measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result; determining whether to perform cell reselection or report the measurement result to network equipment according to the measurement result; therefore, when the 5G base station is shared, the technology corresponding to the patent can be used for respectively carrying out mobility measurement configuration (cell reselection and switching) on the idle state terminal and the connected state terminal, effectively reducing the measurement overhead and time delay of the terminals under the conditions of low system information overhead and software upgrading, and greatly improving the user experience.

Drawings

FIG. 1 is a schematic diagram of a network architecture according to an embodiment of the present invention;

fig. 2A is a schematic flow chart illustrating an implementation of the information configuration method according to the embodiment of the present invention;

FIG. 2B is a schematic diagram of an implementation flow of the information configuration method according to the embodiment of the present invention;

FIG. 3 is a schematic diagram of an implementation flow of an information configuration method according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of an implementation flow of an information configuration method according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of an implementation flow of an information configuration method according to an embodiment of the present invention;

FIG. 6A is a first block diagram illustrating an information configuration according to an embodiment of the present invention;

FIG. 6B is a schematic diagram of a second exemplary configuration of information configuration according to the present invention;

fig. 7 is a schematic diagram of a hardware entity of a computer device according to an embodiment of the present invention.

Detailed Description

Compared with the traditional 2G/3G/4G system, the 5G system has higher deployment frequency, smaller single station coverage range and greatly improved station site density. Operators will invest a large amount of infrastructure investment to build the 5G network, and the subsequent operation optimization maintenance cost will also increase sharply. These heavy costs will eventually lead to the user cost not being reduced, user penetration and business popularity will be severely affected, and will pose a serious challenge to 5G business development. In the 5G era, in order to reduce the cost of network construction and maintenance, many domestic and foreign operators and expert scholars including chinese operators all express the sound of reducing the deployment cost of the 5G co-construction shared base station.

Currently, a 4G system can send a plurality of Public Land Mobile Network (PLMN) identifiers in base station broadcast information, attach to a base station when a terminal recognizes that the PLMN and a frequency point of the base station are both supportable, initiate a random access request to the base station when a service arrives, perform corresponding wireless Network access and core Network authentication, and establish service connection after the service arrives. The method realizes the sharing of the base station of the operator.

Due to time and application scenario limitations, the 4G era has not performed any special performance optimization for multiple operators to share a base station. Especially, in the cell selection and cell reselection measurement of the terminal in an idle state and the mobility measurement in a connected state, the terminal needs to measure all cells corresponding to all frequency points of all operators broadcasted by the base station, and the measurement overhead is very large. The 5G terminal specified in the current standard needs to have the capability of measuring 13 frequency points in total, including 2G/3G/4G/5G frequency points, usually 1-2G frequency points, 3-5G frequency points, 3-4G frequency points, 6-10 5G frequency points are available for one operator, and 13-21 frequency points exist for one operator, if a network sharing mode is considered and 2-3 operators serve at the same time, the frequency points needing to be measured have 26-45 frequency points in total, and the measuring capability of the current 5G terminal is far exceeded. In the 5G era, frequency points and cells to be measured by the terminal are increased by more than 10 times compared with the 4G era, and if optimization is not performed, the measurement power consumption, measurement evaluation and access delay of the terminal are increased sharply, so that the user experience of the 5G terminal is seriously influenced.

The technical solution of the present invention is further elaborated below with reference to the drawings and the embodiments.

In this embodiment, a network architecture is provided first, and fig. 1 is a schematic diagram of a composition structure of the network architecture according to the embodiment of the present invention, as shown in fig. 1, the network architecture includes two or more terminals 11, 12, 13, and 1N and a network device 31, where the terminals 11, 12, 13, and 1N interact with the network device 31 through a network 21. The terminal may be implemented as various types of devices having information processing capabilities, such as a mobile phone, a tablet computer, a desktop computer, a personal digital assistant, a navigator, a digital phone, a video phone, a television, a sensing device, and so on.

The embodiment provides an information configuration method, which is applied to a terminal, and the functions implemented by the method can be implemented by calling a program code by a processor in the terminal, although the program code can be stored in a computer storage medium, and thus, the terminal at least comprises the processor and the storage medium.

Fig. 2A is a schematic view of an implementation flow of an information configuration method according to an embodiment of the present invention, and as shown in fig. 2A, the method includes:

step S200, receiving configuration information sent by network equipment;

step S201, determining a frequency point related to mobility management and/or a cell corresponding to the frequency point according to the configuration information and an operator network identifier to which the terminal belongs;

here, the mobility management includes: cell reselection, network controlled mobility or handover.

In other embodiments, the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information; the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step S202, measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measuring result;

step S203, determining whether to perform cell reselection or report the measurement result to the network device according to the measurement result.

The embodiment shown in FIG. 2A will now be described in detail:

the embodiment provides an information configuration method, which includes:

step A11, receiving configuration information sent by a network device;

step A12, determining frequency points related to cell reselection according to the configuration information and the operator network identifier to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

and reselecting related second configuration information of the inter-system cell, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information;

in other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step A13, measuring the frequency points to obtain a measurement result;

step A14, determining whether to perform cell reselection or report the measurement result to the network device according to the measurement result.

The embodiment provides an information configuration method, which includes:

step A21, receiving configuration information sent by a network device;

step A22, determining a cell corresponding to a frequency point relevant to cell reselection according to the configuration information and an operator network identifier to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

and reselecting related second configuration information of the inter-system cell, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information;

in other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step A23, measuring the cell corresponding to the frequency point to obtain a measurement result;

step A24, determining whether to perform cell reselection or report the measurement result to the network device according to the measurement result.

An embodiment proposes an information configuration method, the method comprising:

step A31, receiving configuration information sent by a network device;

step A32, determining a cell corresponding to a frequency point and a frequency point related to cell reselection according to the configuration information and an operator network identifier to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

and reselecting related second configuration information of the inter-system cell, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information includes the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and the second different system frequency point information and a second network identifier corresponding to the second different system frequency point information.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step A33, measuring the frequency point and the cell corresponding to the frequency point to obtain the measuring result;

step A34, determining whether to perform cell reselection or report the measurement result to the network device according to the measurement result.

The embodiment provides an information configuration method, which includes:

step B11, receiving the configuration information sent by the network equipment;

step B12, according to the configuration information and the operator network identification to which the terminal belongs, determining the frequency point related to the network control mobility and/or the cell corresponding to the frequency point;

in other embodiments, the configuration information includes at least one of:

the network controls third configuration information related to mobility, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls fourth configuration information related to mobility, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step B13, measuring the frequency point and/or the cell corresponding to the frequency point to obtain the measuring result;

and step B14, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment provides an information configuration method, which includes:

step B21, receiving the configuration information sent by the network equipment;

step B22, according to the configuration information and the operator network identification to which the terminal belongs, determining the frequency point and the cell corresponding to the frequency point related to the network control mobility;

in other embodiments, the configuration information includes at least one of:

the network controls third configuration information related to mobility, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls fourth configuration information related to mobility, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step B23, measuring the frequency point and the cell corresponding to the frequency point to obtain the measuring result;

and step B24, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment provides an information configuration method, which includes:

step B31, receiving the configuration information sent by the network equipment;

step B32, determining a cell corresponding to the frequency point related to network control mobility according to the configuration information and the operator network identifier to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

the network controls third configuration information related to mobility, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls fourth configuration information related to mobility, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step B33, measuring the cell corresponding to the frequency point to obtain a measuring result;

and step B34, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment provides an information configuration method, which includes:

step C11, receiving the configuration information sent by the network device;

step C12, determining the frequency point related to switching according to the configuration information and the operator network identification to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

switching related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or a network identifier corresponding to the pilot frequency point information;

and switching related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identifications corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step C13, measuring the frequency points to obtain a measurement result;

and step C14, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment provides an information configuration method, which includes:

step C21, receiving the configuration information sent by the network device;

step C22, determining the cell corresponding to the frequency point relevant to the switching according to the configuration information and the operator network identification to which the terminal belongs;

in other embodiments, the configuration information includes at least one of:

switching related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or a network identifier corresponding to the pilot frequency point information;

and switching related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identifications corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step C23, measuring the cell corresponding to the frequency point to obtain a measurement result;

and step C24, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

The embodiment provides an information configuration method, which includes:

step C31, receiving the configuration information sent by the network device;

step C32, determining the frequency point and the corresponding cell of the frequency point for switching according to the configuration information and the operator network identification of the terminal;

in other embodiments, the configuration information includes at least one of:

switching related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or a network identifier corresponding to the pilot frequency point information;

and switching related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identifications corresponding to the different system frequency point information.

The third configuration information includes at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information, and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

Step C33, measuring the frequency point and the cell corresponding to the frequency point to obtain the measuring result;

and step C34, determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

In other embodiments, the configuration information includes at least one of:

the first configuration information comprises the pilot frequency point information and at least one network identifier corresponding to the pilot frequency point information;

the second configuration information comprises the inter-system frequency point information and at least one network identifier corresponding to the inter-system frequency point information;

the third configuration information comprises the pilot frequency point information and/or at least one network identifier corresponding to the pilot frequency point;

the fourth configuration information includes the inter-system frequency point information and/or at least one network identifier corresponding to the inter-system frequency point.

In other embodiments, the configuration information includes at least one of:

when the first configuration information contains a network identifier corresponding to the pilot frequency point information, the first configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the second configuration information contains a network identifier corresponding to the inter-system frequency point information, the second configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the third configuration information contains a network identifier corresponding to the pilot frequency point information, the third configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

and when the fourth configuration information contains a network identifier corresponding to the inter-system frequency point information, the fourth configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment.

In other embodiments, the determining, by the terminal, a frequency point related to mobility management and/or a cell corresponding to the frequency point includes:

step A1, the terminal determines the network identifier of the operator from the memory or the SIM card, or the terminal determines the network identifier of the operator according to the IMSI;

step A2, the terminal determines, according to the network identifier of the operator to which the terminal belongs, frequency point information corresponding to the network identifier in the configuration information that is the same as the network identifier of the operator to which the terminal belongs, as a frequency point and/or a cell corresponding to the frequency point, which is relevant to the terminal for mobility management.

In other embodiments, the method further comprises: and receiving the configuration information sent by the network equipment through receiving a system message or a special message.

In other embodiments, the method further comprises: and when the receiving power or the receiving quality of the signal of the resident cell is smaller than a first preset threshold, starting cell reselection measurement, and measuring a frequency point or a cell corresponding to the frequency point, which is contained in the first configuration information and/or the second configuration information and is the same as the network identifier of the operator to which the terminal belongs, to obtain a measurement result.

In other embodiments, the method further comprises: and when the measurement result is greater than a second preset threshold, reselecting the corresponding cell.

In other embodiments, the measuring the frequency point and/or the cell corresponding to the frequency point to obtain the measurement result includes: the terminal measures a frequency point or a cell corresponding to the frequency point which is the same as the network identifier of the operator to which the terminal belongs, and obtains a measurement result.

In other embodiments, the determining whether to perform cell reselection or report the measurement result to the network device according to the measurement result includes: and when the terminal is in a connected state, the terminal reports the measurement result to the network equipment so that the network equipment determines whether the terminal needs to be switched.

In other embodiments, the cell signal includes at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

The embodiment proposes an information configuration method, which is applied to a network device, and the functions implemented by the method may be implemented by a processor in the network device calling a program code, which may be stored in a computer storage medium.

Fig. 2B is a schematic view of an implementation flow of the information configuration method according to the embodiment of the present invention, and as shown in fig. 2B, the method includes:

step S211, determining configuration information;

the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information; the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the determining the configuration information includes: and configuring the configuration information according to the network sharing information. Wherein the network sharing information comprises: the first network identification and the corresponding pilot frequency point information and/or the different system frequency point information, and the second network identification and the corresponding pilot frequency point information and/or the different system frequency point information.

Step S212, sending the configuration information to the terminal.

In other embodiments, the first configuration information includes the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and the second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information; the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the configuration information includes at least one of:

the first configuration information comprises the pilot frequency point information and at least one network identifier corresponding to the pilot frequency point information;

the second configuration information comprises the inter-system frequency point information and at least one network identifier corresponding to the inter-system frequency point information;

the third configuration information comprises the pilot frequency point information and/or at least one network identifier corresponding to the pilot frequency point;

the fourth configuration information includes the inter-system frequency point information and/or at least one network identifier corresponding to the inter-system frequency point.

In other embodiments, the configuration information includes at least one of:

when the first configuration information contains a network identifier corresponding to the pilot frequency point information, the first configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the second configuration information contains a network identifier corresponding to the inter-system frequency point information, the second configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the third configuration information contains a network identifier corresponding to the pilot frequency point information, the third configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

and when the fourth configuration information contains a network identifier corresponding to the inter-system frequency point information, the fourth configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment.

In other embodiments, the first network identification is a network identification of an operator to which the network device belongs;

the second network identification is a network identification of an operator sharing the network device.

In other embodiments, the first configuration information is sent via a system message;

the second configuration information is sent via a system message;

the third configuration information is sent through an RRC message;

the fourth configuration information is transmitted through an RRC message.

In other embodiments, the method further comprises:

step B1, receiving the measurement result of the receiving power or the receiving quality of at least one cell signal on the frequency point reported by the terminal;

step B2, when the difference between the measurement result and a second measurement value obtained by measuring the received power or the received quality of the serving cell signal by the terminal is greater than a preset third threshold, initiating a handover request to the cell corresponding to the measurement result.

In other embodiments, the cell signal includes at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

In other embodiments, the method further comprises: determining home operator information of the terminal; and determining configuration information for the terminal according to the home operator information of the terminal.

Wherein the determining the home operator information of the terminal includes: and determining the home operator information of the terminal according to the IMSI identifier of the terminal.

Wherein the determining the configuration information for the terminal according to the home operator information of the terminal includes: and determining frequency point information corresponding to the network identifier of the home operator of the terminal as configuration information of the terminal according to the network identifier of the home operator of the terminal and the network sharing information.

In other embodiments, the network identification is a public land mobile network identification.

In other embodiments, the network identifier is sent in an implicit manner, including: the network equipment determines a configuration information list, wherein each piece of information in the configuration information list corresponds to a specific network identifier; or the network device segments the configuration information, and each segment corresponds to a specific network identifier.

The embodiment of the invention provides an information configuration method, which comprises the following steps:

step S1, the terminal determines the frequency point to be measured and/or the cell corresponding to the frequency point to be measured according to the received configuration information;

wherein the configuration information comprises at least one of: the method comprises the steps of carrying out first configuration information of pilot frequency measurement for cell reselection, second configuration information of inter-system measurement for cell reselection, third configuration information of handover measurement and measurement configuration information;

the first configuration information comprises frequency point information of pilot frequency measurement and operator identification corresponding to the frequency point; the second configuration information comprises an inter-system identifier, measured frequency point information and an operator identifier corresponding to a frequency point; the third configuration information comprises frequency point information of a switching measurement frequency point complete set and operator identification corresponding to the frequency point; the measurement configuration information comprises a frequency point to be measured and/or a list and an identification of a cell to be measured corresponding to the frequency point to be measured, and the frequency point to be measured is a switching measurement frequency point corresponding to the operator identification of the terminal.

Step S2, the terminal measures the frequency points with the same operator identification corresponding to the terminal to obtain the measuring result;

in other embodiments, the same frequency point includes at least one of: the same pilot frequency point, different system frequency point and frequency point to be measured.

The operator identification corresponding to the terminal comprises: and the operator identifier of the contracted operator corresponding to the terminal or the operator identifier of the home operator corresponding to the terminal.

Step S3, the terminal determines whether to switch/access according to the measurement result.

In other embodiments, the method further comprises: and the terminal receives the configuration information sent by the network equipment in a broadcast mode or a unicast mode.

The present embodiment provides an information configuration method, which is described by taking an idle state as an example, where in the idle state, configuration information received by a terminal is first configuration information and second configuration information. The method comprises the following steps:

step S11, the terminal receives the configuration information sent by the network device in a broadcast mode or a unicast mode.

Step S12, the terminal determines the frequency point to be measured and/or the cell corresponding to the frequency point to be measured according to the received configuration information;

wherein the configuration information comprises at least one of: the first configuration information is used for carrying out pilot frequency measurement of cell reselection, and the second configuration information is used for carrying out inter-system measurement of cell reselection;

the first configuration information comprises frequency point information of pilot frequency measurement and operator identification corresponding to the frequency point; the second configuration information comprises an inter-system identifier, measured frequency point information and an operator identifier corresponding to a frequency point;

step S13, when the receiving power or receiving quality of the cell signal is less than the first preset threshold, the terminal starts cell reselection measurement, and measures the frequency point which is contained in the first configuration information and/or the second configuration information and is the same as the operator identification of the terminal, and obtains the measurement result.

Here, step S13 provides a method that implements step S202 in an idle state.

In other embodiments, the same frequency point includes at least one of: the same pilot frequency point, different system frequency point and frequency point to be measured. The operator identification corresponding to the terminal comprises: and the operator identifier of the contracted operator corresponding to the terminal or the operator identifier of the home operator corresponding to the terminal.

And step S14, when the terminal determines that the measurement result of the cell signal is greater than a second preset threshold, reselecting the corresponding cell.

Wherein the cell signal comprises at least one of: downlink reference signals, synchronization signals and channel state indication signals of the cell.

Here, step S14 provides a method that implements step S203 in an idle state.

In this embodiment, a connection state is taken as an example for explanation, and in the connection state, the configuration information received by the terminal is the third configuration information. The method comprises the following steps:

step S21, the terminal receives the configuration information sent by the network device in a broadcast mode or a unicast mode.

Step S22, the terminal determines the frequency point to be measured and/or the cell corresponding to the frequency point to be measured according to the received configuration information;

the configuration information is third configuration information, and the third configuration information comprises frequency point information of a switching measurement frequency point complete set and operator identification corresponding to the frequency point;

and step S23, the terminal measures the determined frequency point to be measured which is the same as the sign operator mark or the attribution operator mark, and obtains the measurement result of the receiving power or the receiving quality of a plurality of cell signals on the frequency point to be measured.

Here, step S23 provides a method that implements step S202 in an idle state.

In other embodiments, the same frequency point includes at least one of: the same pilot frequency point, different system frequency point and frequency point to be measured. The operator identification corresponding to the terminal comprises: and the operator identifier of the contracted operator corresponding to the terminal or the operator identifier of the home operator corresponding to the terminal.

Step S24, the terminal reports the measurement result to the network device, so that the network device determines whether to perform handover.

Here, the network device receives the measurement results of the received power or the received quality of the signals of the cells on the frequency point to be measured, which are reported by the terminal;

and the network equipment determines that when the difference between the measurement result and a second measurement value obtained by measuring the receiving power or the receiving quality of the cell signal by the terminal is greater than a preset third threshold, the network equipment initiates a switching request to the cell corresponding to the measurement result.

Wherein the cell signal comprises at least one of: downlink reference signals, synchronization signals and channel state indication signals of the cell.

Here, step S24 provides a method that implements step S203 in an idle state.

The embodiment provides an information configuration method, which is applied to network equipment and comprises the following steps:

step S41, the network device configures the configuration information for the terminal according to the base station shared subscription information between the operators;

wherein the sharing of the subscription information by the inter-operator base station includes: and the pilot frequency points to be tested and/or the corresponding cells of the operator of the network equipment are shared.

Step S42, the network device sends configuration information to the terminal, where the configuration information is used for inter-frequency measurement and/or inter-system measurement for cell reselection.

Wherein the configuration information comprises at least one of: the method comprises the steps of carrying out first configuration information of pilot frequency measurement for cell reselection, second configuration information of inter-system measurement for cell reselection, third configuration information of handover measurement and measurement configuration information;

the first configuration information comprises frequency point information of pilot frequency measurement and operator identification corresponding to the frequency point; the second configuration information comprises an inter-system identifier, measured frequency point information and an operator identifier corresponding to a frequency point; the third configuration information comprises frequency point information of a switching measurement frequency point complete set and operator identification corresponding to the frequency point; the measurement configuration information comprises a frequency point to be measured and/or a list and an identification of a cell to be measured corresponding to the frequency point to be measured, and the frequency point to be measured is a switching measurement frequency point corresponding to the operator identification of the terminal.

In other embodiments, when the terminal is in the connected state, the method further includes:

step S31, the network equipment receives the measurement results of the received power or the received quality of the signals of a plurality of cells on the frequency point to be measured, which are reported by the terminal;

step S32, the network device determines that when the difference between the measurement result and a second measurement value obtained by measuring the received power or the received quality of the cell signal by the terminal is greater than a preset third threshold, the network device initiates a handover request to the cell corresponding to the measurement result.

In other embodiments, the configuring information includes measurement configuring information, and when the terminal is in a connected state, the configuring information is configured for the terminal by the network device according to subscription information shared by base stations between operators, including:

step S41, the network device obtains an operator identifier of the terminal;

step S42, the network device determines the measurement configuration information for the terminal according to the heavily loaded operator mark and the base station shared subscription information between operators;

step S43, the measurement configuration information includes a frequency point to be measured and/or a list and an identification of a cell to be measured corresponding to the frequency point to be measured, and the frequency point to be measured is a switched measurement frequency point corresponding to the operator identification of the terminal.

The schemes will be set forth below according to whether the terminal is in an idle state or a connected state, respectively, where the idle state includes one solution and the connected state includes two solutions.

Idle state solution

The present embodiment provides an information configuration method, and fig. 3 is a schematic view of an implementation flow of the information configuration method according to the embodiment of the present invention, as shown in fig. 3, the method includes:

step S301, the network equipment sends first configuration information of pilot frequency measurement for cell reselection and/or second configuration information of pilot system measurement;

the first configuration information and/or the second configuration information are configured by the network device according to the inter-operator base station shared subscription information, for example, the inter-operator base station shared subscription information includes the pilot frequency to be detected frequency point and/or the corresponding cell of the operator to which the network device belongs, the pilot frequency to be detected frequency point and/or the corresponding cell of the operator sharing the network device, and the like, and the network device configures the first configuration information and/or the second configuration information according to the inter-operator base station shared subscription information.

The first configuration information and the second configuration information are sent in a broadcast manner or in a unicast manner (such as RRC signaling) (the broadcast manner sends a corresponding idle state scheme, and the unicast manner sends a corresponding idle state and/or connected state scheme).

The first configuration information comprises frequency point information of pilot frequency measurement, a first identifier corresponding to the frequency point, an adjacent cell list optionally comprising the frequency point of pilot frequency measurement, and a cell reselection priority optionally comprising the frequency point of pilot frequency measurement.

The second configuration information comprises an inter-system identifier, measured frequency point information, a second identifier corresponding to the frequency point, an adjacent cell list optionally comprising the frequency point measured by the inter-system, and a cell reselection priority optionally comprising the frequency point measured by the inter-system.

The first identifier and the second identifier indicate an operator identifier to which the frequency point belongs, and the operator identifier may be a PLMN number, an operator number, or the like; the first and second identities may be one or more PLMN numbers or operator numbers.

If the first identifier (the second identifier) includes multiple PLMN numbers or operator numbers, the cell reselection priorities corresponding to the PLMN numbers or operator numbers may be different for the frequency points of each inter-frequency measurement (inter-system measurement).

The inter-system identifier may be explicitly sent, for example, the inter-system identifier may be an enumerated value, when the value of the enumerated value is 1, the corresponding inter-system is a 2G system (GSM/CDMA), when the value of the enumerated value is 2, the corresponding inter-system is a 3G system (WCDMA/TD-SCDMA), and when the value of the enumerated value is 3, the corresponding inter-system is a 4G system (TD-LTE/LTE FDD); the inter-system identifier may also be implicitly sent, for example, a specific inter-system is corresponding to a specific system information block position, for example, a 2G system (GSM/CDMA) is corresponding to the system information block position 1, a 3G system (WCDMA/TD-SCDMA) is corresponding to the system information block position 2, and a 4G system (TD-LTE/LTE FDD) is corresponding to the system information block position 3.

Step S302, the terminal receives the first configuration information of the pilot frequency measurement for cell reselection and/or the second configuration information of the inter-system measurement;

step S303, the terminal judges according to the operator identification corresponding to the signing operator or the operator identification corresponding to the attributive operator, and determines the frequency point to be measured and/or the cell corresponding to the frequency point to be measured;

for example, an operator identifier corresponding to an operator subscribed by the terminal is PLMN _1, the first configuration information includes three frequency points, the operator identifier corresponding to the frequency point one is PLMN _1, the operator identifier corresponding to the frequency point two is PLMN _2, and the operator identifier corresponding to the frequency point three is PLMN _ 3; the terminal judges the frequency point I to be measured, and the optional terminal further reads a cell list corresponding to the frequency point I to determine the cell identifier in the cell list.

For example, an operator identifier corresponding to an operator subscribed by the terminal is PLMN _1, the first configuration information includes three frequency points, the operator identifier corresponding to the frequency point one is PLMN _1, the operator identifiers corresponding to the frequency point two are PLMN _1 and PLMN _2, and the operator identifier corresponding to the frequency point three is PLMN _ 3; the terminal judges the frequency point I and the frequency point II to be measured, and the optional terminal further reads a cell list corresponding to the frequency point I and the frequency point II and determines the cell identification in the cell list.

Step S304, the terminal measures the determined pilot frequency point and/or pilot system frequency point and/or frequency point to be measured which are the same with the operator identification corresponding to the signing operator or the operator identification corresponding to the attributive operator;

step S305, when the receiving power or the receiving quality of a downlink reference signal, a sum of synchronous signals, a sum of channel state indication signals and a sum of downlink reference signals of a cell (base station) is smaller than a first preset threshold, the terminal starts cell reselection measurement, and measures frequency points which are contained in first configuration information, sum of second configuration information and are the same as an operator identifier of the terminal to obtain a first measured value;

step S306, when the terminal determines that the first measurement value of a certain cell is greater than the second preset threshold, reselecting to the certain cell.

The first connected state solution: the network equipment sends a switching measurement frequency point complete set, and the terminal selects a frequency point which is required to be measured from the switching measurement frequency point complete set.

The present embodiment provides an information configuration method, and fig. 4 is a schematic view of an implementation flow of the information configuration method according to the embodiment of the present invention, as shown in fig. 4, the method includes:

step S401, the network device sends third configuration information for handover measurement, where the third configuration information is sent in a unicast manner (e.g. RRC signaling);

the third configuration information includes information of the frequency point to be detected, and a third identifier corresponding to the frequency point, optionally including a neighbor cell list corresponding to the frequency point to be detected.

The third identifier indicates an operator identifier to which the frequency point belongs, and may be a PLMN number, an operator number, or the like; the third identification may be a plurality of PLMN numbers or an operator number.

The inter-system identifier may be explicitly sent, for example, the inter-system identifier may be an enumerated value, when the value of the enumerated value is 1, the corresponding inter-system is a 2G system (GSM/CDMA), when the value of the enumerated value is 2, the corresponding inter-system is a 3G system (WCDMA/TD-SCDMA), and when the value of the enumerated value is 3, the corresponding inter-system is a 4G system (TD-LTE/LTE FDD); the inter-system identifier may also be implicitly sent, for example, a specific inter-system is corresponding to a specific system information block position, for example, a 2G system (GSM/CDMA) is corresponding to the system information block position 1, a 3G system (WCDMA/TD-SCDMA) is corresponding to the system information block position 2, and a 4G system (TD-LTE/LTE FDD) is corresponding to the system information block position 3.

Step S402, the terminal receives the third configuration information for performing switching measurement;

step S403, the terminal judges according to the sign operator mark or the attribution operator mark, and determines the frequency point to be measured of the corresponding terminal and/or the cell corresponding to the frequency point to be measured in the third configuration information;

for example, the identifier of the operator subscribed to the terminal is PLMN _1, the third configuration information includes three frequency points, the identifier of the operator corresponding to the frequency point one is PLMN _1, the identifier of the operator corresponding to the frequency point two is PLMN _2, and the identifier of the operator corresponding to the frequency point three is PLMN _ 3; the terminal judges the frequency point I to be measured, and the optional terminal further reads a cell list corresponding to the frequency point I to determine the cell identifier in the cell list.

For example, the identifier of the operator subscribed to the terminal is PLMN _1, the third configuration information includes three frequency points, the identifier of the operator corresponding to the frequency point one is PLMN _1, the identifiers of the operators corresponding to the frequency point two are PLMN _1 and PLMN _2, and the identifier of the operator corresponding to the frequency point three is PLMN _ 3; the terminal judges the frequency point I to be measured, and the optional terminal further reads a cell list corresponding to the frequency point I to determine the cell identifier in the cell list.

Step S404, the terminal measures the determined frequency point to be measured which is the same as the sign of the signed operator or the sign of the attributive operator, and obtains a third measured value of the receiving power or the receiving quality of the downlink reference signals and/or the synchronizing signals and/or the channel state indicating signals of a plurality of cells on the frequency point to be measured;

step S405, the terminal reports a third measured value to the network equipment;

step S406, the network device determines that when the difference between the third measurement value and a second measurement value obtained by measuring the reception power or the reception quality of the downlink reference signal, or the synchronization signal, or the channel state indication signal of the terminal in the local cell (the network device) is greater than a preset third threshold, the network device initiates a handover request to the cell corresponding to the third measurement value.

Connection state solution two: the network equipment sends a corresponding switching measurement frequency point for the terminal according to the operator identification of the terminal;

the present embodiment provides an information configuration method, and fig. 5 is a schematic view of an implementation flow of the information configuration method according to the embodiment of the present invention, as shown in fig. 5, the method includes:

step S411, the network equipment obtains first identification information of an operator identification of the terminal;

the first identification information is obtained from a core network by a network device, or reported to the network device by a terminal, for example, the terminal carries the first identification information when the RRC connection establishment is completed;

step S412, the network device determines the measurement configuration information for the terminal according to the first identification information and the shared subscription information of the base stations between the operators;

here, the inter-operator base station shared subscription information may be understood as network shared information, which includes a frequency point shared by an operator, and the operator sharing the network device needs to configure the frequency point/cell of which different frequency, different system cell reselection, and handover to its home terminal.

The measurement configuration information comprises a frequency point to be measured and/or a list and an identifier of a cell to be measured corresponding to the frequency point to be measured, and the operator identifier of the frequency point to be measured is the same as the operator identifier contained in the first identifier information;

step S413, the network device sends measurement configuration information to the terminal through a dedicated signaling;

and step S414, the terminal receives the measurement configuration information and measures the cell corresponding to the frequency point contained in the measurement configuration information.

Example (b):

suppose that 2 operators (a and B) in the 3.5GHz band of china deploy a 5G network in a base station sharing manner, where the identifier of the operator a is PLMN _1, which is the owner of the base station entity, and the identifier of the operator B is PLMN _2, which is the leaser of the base station.

The first implementation mode comprises the following steps:

step S501, the operator A configures first configuration information for performing pilot frequency measurement for cell reselection in a certain broadcast information block (SystemInformationBlockType _ x) of the 5G base station;

the message format of the first configuration information is as follows:

SystemInformationBlockType_x

{

interfrequencycarrierfrequencyist-the first configuration information, is the list of pilot frequency measurement configuration information of operator A base station, the list contains N pieces of pilot frequency point information Interfrequencycarrierfrequencyinformation

}

The format of the ith information unit, namely, the InterFrequencyCarrierFrequencyInformation _ i, is as follows:

InterFrequency Carrier frequency information _ i-configuration information of the frequency point i of the pilot frequency to be measured (different frequency point from the frequency point used by the base station is the pilot frequency)

{

Operator ID _ i-operator identification corresponding to different frequency point i, assumed to be PLMN _1

DL-Carrier frequency _ i-down central frequency point position information NARFCN _1 of pilot frequency point i

{

InterfrequencyneghborCellList _ i-the adjacent cell list of the pilot frequency point i contains M cell identifications using the frequency point i adjacent to the base station

{

PysicalCellID _ i-cell identification

}

}

The format of the jth information unit, namely, the interfrequencycarrierfrequency information _ j, is as follows:

InterFrequency Carrier frequency information _ j-configuration information of the frequency point j of the pilot frequency to be measured (different frequency point from the frequency point used by the base station is the pilot frequency)

{

Operator ID _ j-operator ID corresponding to the different frequency point j, assumed to be PLMN _2

DL-Carrier frequency _ j-position information NARFCN _2 of down-going center frequency point of pilot frequency point j

{

InterfrequencyneghborCellList _ j-neighbor cell list of pilot frequency point j contains K cell identifications using frequency point j adjacent to the base station

{

PysicalCellID _ j-cell identification

}

}

Step S502, a first terminal (assuming that the identifier of a contracted operator is PLMN _1) receives first configuration information which is broadcasted by the base station and used for performing pilot frequency measurement of cell reselection;

step S503, the first terminal judges according to the signed operator identifier (PLMN _1), and determines to read the frequency point information to be measured DL-Carrier frequency _ i which is contained in the first configuration information and reselected by the first terminal cell, and the corresponding adjacent cell list information interfrequency neighbor cell List _ i;

step S504, the first terminal measures the cell with the center frequency point positioned in NARFCN _1, and measures according to the adjacent cell in the interfrequencyNeighborCellList _ i during measurement;

step S505, when the receiving power or receiving quality of the downlink reference signal and/or the synchronization signal and/or the channel state indication signal of the cell is smaller than a first preset threshold, the first terminal starts to measure the receiving power or receiving quality of the downlink reference signals and/or the synchronization signal and/or the channel state indication signal of a plurality of adjacent cells included in the inter frequency neighbor cell list _ i, so as to obtain a first measurement value (when the first terminal performs measurement, the pysicalcellld _ i may be used to perform correlation detection, determine the reference signal of the cell to be measured, perform measurement based on the determination, and obtain the first measurement value);

step S506, when the first terminal determines that the first measurement value of a certain cell (the second base station) is higher than the second preset threshold (the cell reselection threshold), the first terminal reselects to the second base station.

The second embodiment:

step S601, the operator A configures first configuration information for performing pilot frequency measurement of cell reselection in a certain broadcast information block (SystemInformationBlockType _ x) of the 5G base station;

the message format of the first configuration information is as follows:

SystemInformationBlockType_x

{

interfrequencycarrierfrequencyist-the first configuration information, is the list of pilot frequency measurement configuration information of operator A base station, the list contains N pieces of pilot frequency point information Interfrequencycarrierfrequencyinformation

}

The ith pilot frequency point information format is as follows:

InterFrequency Carrier frequency information _ i-configuration information of the frequency point i of the pilot frequency to be measured (different frequency point from the frequency point used by the base station is the pilot frequency)

{

OperatoriD _ i-operator identification of the affiliation of the different frequency point i, assumed to be PLMN _1

DL-Carrier frequency _ i-down central frequency point position information NARFCN _1 of pilot frequency point i

Cell reselection priority of CellReselection priority _ i-pilot frequency point i is 1

{

InterfrequencyneghborCellList _ i-the adjacent cell list of the pilot frequency point i contains M cell identifications using the frequency point i adjacent to the base station

{

PysicalCellID _ i-cell identification

}

}

The jth pilot frequency point information format is as follows:

InterFrequency Carrier frequency information _ j-configuration information of the frequency point j of the pilot frequency to be measured (different frequency point from the frequency point used by the base station is the pilot frequency)

{

OperatoriD _ j-operator identification of the affiliation of the pilot frequency point j, assumed to be PLMN _2

OperatoriD _ j' -operator ID of the different frequency point j, supposing PLMN _1 (frequency point j is shared by operator 1 and operator 2)

DL-Carrier frequency _ j-position information NARFCN _2 of down-going center frequency point of pilot frequency point j

Cell reselection priority _ j of PLMN _2 of pilot frequency point j is 0

CellReselectionpriority _ j' -cell reselection priority 2 of PLMN _1 of inter-frequency bin j

{

InterfrequencyneghborCellList _ j-neighbor cell list of pilot frequency point j contains K cell identifications using frequency point j adjacent to the base station

{

PysicalCellID _ j-cell identification

}

}

Step S602, the first terminal (assuming that the identifier of the contracted operator is PLMN _1) receives first configuration information, broadcasted by the base station, for performing inter-frequency measurement for cell reselection;

step S603, the first terminal judges according to the signed operator identifier (PLMN _1), and determines to read frequency point information DL-Carrier frequency _ i and DL-Carrier frequency _ j to be detected, which are reselected by the first terminal and are contained in the first configuration information, and corresponding adjacent cell list information, i.e. inter frequency neighbor cell List _ i and i.e. inter frequency neighbor cell List _ j;

step S604, the first terminal measures the cells of the central frequency point in NARFCN _1 and NARFCN _2, determines the priority of the frequency point according to the cell reselection priority CellReselectionpriority _ i and CellReselectionpriority _ j' during measurement, and measures the adjacent cells in the interfrequency NeighborCellList _ i and the interfrequency NeighborCellList _ j;

step S605, when the receiving power or receiving quality of the downlink reference signal and/or the synchronization signal and/or the channel state indication signal of the cell is smaller than a first preset threshold, the first terminal starts to measure the receiving power or receiving quality of the downlink reference signals and/or the synchronization signal and/or the channel state indication signal of a plurality of adjacent cells included in the inter frequency neighborcelllist _ i and the inter frequency neighborcelllist _ j, and obtains a first measurement value (when the first terminal performs measurement, the first terminal performs correlation detection by using pysicalcellld _ i and pysicalcellld _ j, determines the reference signal of the cell to be measured, performs measurement by using the reference signal and obtains the first measurement value);

step S606, when the first terminal determines that the first measurement value of a certain cell (second base station) is higher than a second preset threshold (cell reselection threshold), the first terminal reselects the second base station;

the terminal preferentially reselects to a high-priority cell (in this embodiment, the priority of the frequency point j is higher), and when the cells in the frequency point i and the frequency point j both meet the reselection threshold, preferentially reselects to the cell where the frequency point j is located.

The third embodiment is as follows:

step S701, the operator a configures second configuration information for performing inter-system measurement for cell reselection in a certain broadcast information block (systemlnformationblocktype _ x) of its 5G base station, where the inter-system measurement frequency point is an UTRA system in this embodiment;

the message format of the second configuration information is as follows:

SystemInformationBlockType_x

{

carrier frequency List UTRA-the second configuration information, namely the measurement configuration information list of the different system UTRA of the operator A base station, wherein the list comprises N pieces of UTRA different system frequency point information Carrier frequency information UTRA

{

Carrier frequency information UTRA _ i-configuration information of inter-system point i to be tested

{

OperatoriD _ i-operator identification of frequency point i attribution of UTRA different system, assumed to be PLMN _1

DL-Carrier frequency _ i-downlink central frequency point position information NARFCN _1 of UTRA different system frequency point i

{

NeighborCellListUTRA _ i-UTRA different system frequency point i adjacent cell list, containing M cell identifications using frequency point i adjacent to the base station

{

PysicalCellID _ i-cell identification

}

}

}

Carrier frequency information UTRA _ j-configuration information of UTRA different system frequency point j to be tested

{

OperatoriD _ j, operator identification of frequency point j attribution of different UTRA systems, is assumed to be PLMN _2

OperatoriD _ j', the identifier of the operator to which UTRA is attributed the frequency point j of different systems, and is assumed to be PLMN _1 (the frequency point j is shared by the operator 1 and the operator 2)

DL-Carrier frequency _ j-position information NARFCN _2 of down-going center frequency point of UTRA different system frequency point j

{

NeighborCellListUTRA _ j-UTRA different system frequency point j adjacent cell list, comprising K cell identifications adjacent to the base station and using frequency point j

{

PysicalCellID _ j-cell identification

}

}

}

}

Step S702, the first terminal (assuming that the identifier of the contracted operator is PLMN _1) receives second configuration information, broadcasted by the base station, of the inter-system measurement for cell reselection;

step S703, the first terminal judges according to the signed operator identifier (PLMN _1), and determines to read frequency point information to be detected DL-Carrier frequency _ i and DL-Carrier frequency _ j which are contained in the second configuration information and reselected by the cell of the first terminal, and corresponding neighbor cell list information NeighborCellListUTRA _ i and NeighborCellListUTRA _ j;

step S704, the first terminal measures the cells with the central frequency points in NARFCN _1 and NARFCN _2, and measures the adjacent cells according to NeighborCellListUTRA _ i and NeighborCellListUTRA _ j during measurement;

step S705, when the receiving power or receiving quality of the downlink reference signal and/or the synchronization signal and/or the channel state indication signal of the cell is smaller than a first preset threshold, the first terminal starts to measure the receiving power or receiving quality of the downlink reference signal and/or the synchronization signal and/or the channel state indication signal of a plurality of adjacent cells included in NeighborCellListUTRA _ i and NeighborCellListUTRA _ j, and obtains a first measurement value (when the first terminal performs measurement, the first terminal performs correlation detection by using PysicalCellID _ i and PysicalCellID _ j, determines the reference signal of the cell to be measured, performs measurement based on the determination, and obtains the first measurement value);

step S706, when the first terminal determines that the first measurement value of a certain cell (the second base station) is higher than a second preset threshold (the cell reselection threshold), the first terminal reselects to the second base station.

In the above embodiment, the network device configures the pilot frequency andor the inter-system measurement information according to the base station shared subscription information between the operators, the terminal reads the corresponding to-be-measured frequency point andor to-be-measured cell information in the pilot frequency andor the inter-system measurement information sent by the network device according to the operator identifier of the terminal, and the network device configures the mobility measurement configuration information for the connected terminal according to the base station shared subscription information between the operators and the operator identifier information of the terminal.

Compared with the prior art, the embodiment has the following technical advantages: when the 5G base station is shared, the technology corresponding to the patent can be used for respectively carrying out mobility measurement configuration (cell reselection and switching) on the idle state terminal and the connected state terminal, so that the measurement overhead and time delay of the terminal are effectively reduced under the conditions of low system information overhead and software upgrading, and the user experience is greatly improved.

The technical scheme of the embodiment relates to a solution provided for solving the problems of high terminal complexity and high power consumption caused by excessive frequency points in the scene of shared access network co-construction, and the problem also exists in a 4G network, but is not very serious compared with 5G, so that the corresponding application scene is relatively wide.

Due to time and application scenario limitations, the 4G era has not performed any special performance optimization for multiple operators to share a base station. Especially, in the cell selection and cell reselection measurement of the terminal in an idle state and the mobility measurement in a connected state, the terminal needs to measure all cells corresponding to all frequency points of all operators broadcasted by the base station, and the measurement overhead is very large. In the 5G era, frequency points and cells to be measured by the terminal are increased by more than 10 times compared with the 4G era, and if optimization is not performed, the measurement power consumption, measurement evaluation and access delay of the terminal are increased sharply, so that the user experience of the 5G terminal is seriously influenced.

The embodiment provides an information configuration method. The implementation mode is as follows: the network side issues configuration information; the terminal determines the frequency point to be measured and/or the cell corresponding to the frequency point to be measured according to the received configuration information, measures the pilot frequency point and/or the different system frequency point and/or the frequency point to be measured which are determined and are the same as the operator identification corresponding to the signing operator or the operator identification corresponding to the attributive operator, and determines whether to switch/access according to the measurement result.

Based on the foregoing embodiments, an embodiment of the present invention provides an information configuration apparatus, where the apparatus includes each included unit and each module included in each unit, and may be implemented by a processor in a computer device (terminal or network device); of course, the implementation can also be realized through a specific logic circuit; in implementation, the processor may be a Central Processing Unit (CPU), a Microprocessor (MPU), a Digital Signal Processor (DSP), a Field Programmable Gate Array (FPGA), or the like.

Fig. 6A is a first schematic structural diagram of an information configuration according to an embodiment of the present invention, and as shown in fig. 6A, the apparatus 600 includes:

a first receiving unit 601, configured to receive configuration information sent by a network device;

a first determining unit 602, configured to determine a frequency point and/or a cell corresponding to the frequency point related to mobility management according to the configuration information and a network identifier of an operator to which the terminal belongs;

wherein the mobility management comprises: cell reselection, network controlled mobility or handover.

A first measurement unit 603, configured to measure the frequency point and/or a cell corresponding to the frequency point, and obtain a measurement result;

a second determining unit 604, configured to determine whether to perform cell reselection or report the measurement result to the network device according to the measurement result.

In other embodiments, the frequency points include at least one of: different frequency points in the same system and different system frequency points.

In other embodiments, the second determining unit includes:

the first determining module is used for determining the network identifier of the operator from the memory or the SIM card, or determining the network identifier of the operator according to the IMSI;

and the second determining module is used for determining frequency point information corresponding to the network identifier which is the same as the network identifier of the operator to which the terminal belongs in the configuration information as the frequency point related to the mobility management of the terminal and/or the cell corresponding to the frequency point according to the network identifier of the operator to which the terminal belongs.

In other embodiments, the configuration information includes at least one of: the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information; second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information; the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information; and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

In other embodiments, the first configuration information includes the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and the second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information; the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point; the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the apparatus further comprises:

a second receiving unit, configured to receive the configuration information sent by the network device through receiving a system message or a dedicated message.

In other embodiments, the apparatus further comprises:

the starting unit is used for starting cell reselection measurement when the receiving power or the receiving quality of the resident cell signal is smaller than a first preset threshold;

and the second measurement unit is used for measuring the frequency point or the cell corresponding to the frequency point which is contained in the first configuration information and/or the second configuration information and is the same as the network identifier of the operator to which the terminal belongs, and obtaining the measurement result.

In other embodiments, the apparatus further comprises:

and the reselection unit is used for reselecting the corresponding cell when the measurement result is greater than a second preset threshold.

In other embodiments, the first measurement unit is configured to: and measuring the frequency point or the cell corresponding to the frequency point which is the same as the network identifier of the operator to which the terminal belongs to obtain a measuring result.

In other embodiments, the second determining unit is configured to report the measurement result to the network device in a connected state, so that the network device determines whether to perform handover on the terminal.

In other embodiments, the cell signal includes at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

Fig. 6B is a schematic diagram of a second composition structure of information configuration according to an embodiment of the present invention, and as shown in fig. 6B, the apparatus 610 includes:

a third determining unit 611, configured to determine configuration information, where the configuration information includes at least one of: the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information; second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information; the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information; and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

A sending unit 612, configured to send the configuration information to the terminal.

The first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information;

the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information;

the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point;

the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

In other embodiments, the third determining unit is configured to configure the configuration information according to network sharing information.

In other embodiments, the network sharing information includes: the first network identification and the corresponding pilot frequency point information and/or the different system frequency point information, and the second network identification and the corresponding pilot frequency point information and/or the different system frequency point information. Wherein the first network identifier is a network identifier of an operator to which the network device belongs; the second network identification is a network identification of an operator sharing the network device.

In other embodiments, the first configuration information is sent via a system message; the second configuration information is sent via a system message; the third configuration information is sent through an RRC message; the fourth configuration information is transmitted through an RRC message.

In other embodiments, the apparatus further comprises:

a third receiving unit, configured to receive a measurement result of the received power or the received quality of at least one cell signal on the frequency point, where the measurement result is reported by a terminal;

and the initiating unit is used for determining that a switching request is initiated to the cell corresponding to the measuring result when the difference between the measuring result and a second measuring value obtained by measuring the receiving power or the receiving quality of the signal of the service cell by the terminal is greater than a preset third threshold.

In other embodiments, the cell signal includes at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

In other embodiments, the apparatus comprises:

a fourth determining unit configured to determine home operator information of the terminal;

a fifth determining unit, configured to determine configuration information for the terminal according to the home operator information of the terminal.

In other embodiments, the fourth determining unit is configured to determine the home operator information of the terminal according to the terminal IMSI identity.

In other embodiments, the root fifth determining unit is configured to: and determining frequency point information corresponding to the network identifier of the home operator of the terminal as configuration information of the terminal according to the network identifier of the home operator of the terminal and the network sharing information.

In other embodiments, the network identification is a public land mobile network identification.

In other embodiments, the network identifier is sent in an implicit manner, including:

the network equipment determines a configuration information list, wherein each piece of information in the configuration information list corresponds to a specific network identifier; alternatively, the first and second electrodes may be,

and the network equipment segments the configuration information, and each segment corresponds to a specific network identifier.

The above description of the apparatus embodiments, similar to the above description of the method embodiments, has similar beneficial effects as the method embodiments. For technical details not disclosed in the embodiments of the apparatus according to the invention, reference is made to the description of the embodiments of the method according to the invention for understanding.

It should be noted that, in the embodiment of the present invention, if the information configuration method is implemented in the form of a software functional module and is sold or used as a standalone product, the information configuration method may also be stored in a computer readable storage medium. Based on such understanding, the technical solutions of the embodiments of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the methods described in the embodiments of the present invention. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read Only Memory (ROM), a magnetic disk, or an optical disk. Thus, embodiments of the invention are not limited to any specific combination of hardware and software.

Correspondingly, the embodiment of the present invention provides a computer device (including a terminal or a network device), which includes a memory and a processor, where the memory stores a computer program operable on the processor, and the processor executes the computer program to implement the steps in the above method.

Correspondingly, the embodiment of the present invention provides a computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, implements the steps of the above-mentioned method.

Here, it should be noted that: the above description of the storage medium and device embodiments is similar to the description of the method embodiments above, with similar advantageous effects as the method embodiments. For technical details not disclosed in the embodiments of the storage medium and the apparatus according to the invention, reference is made to the description of the embodiments of the method according to the invention.

It should be noted that fig. 7 is a schematic diagram of a hardware entity of a computer device in an embodiment of the present invention, and as shown in fig. 7, the hardware entity of the computer device 700 includes: a processor 701, a communication interface 702, and a memory 703, wherein

The processor 701 generally controls the overall operation of the computer device 700.

The communication interface 702 may enable the computer device to communicate with other terminals or servers via a network.

The memory 703 is configured to store instructions and applications executable by the processor 701, and may also buffer data (e.g., image data, audio data, voice communication data, and video communication data) to be processed or already processed by the processor 701 and modules in the computer device 700, and may be implemented by a FLASH memory (FLASH) or a Random Access Memory (RAM).

It should be appreciated that reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases "in one embodiment" or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. It should be understood that, in various embodiments of the present invention, the sequence numbers of the above-mentioned processes do not mean the execution sequence, and the execution sequence of each process should be determined by its function and inherent logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention. The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described device embodiments are merely illustrative, for example, the division of the unit is only a logical functional division, and there may be other division ways in actual implementation, such as: multiple units or components may be combined, or may be integrated into another system, or some features may be omitted, or not implemented. In addition, the coupling, direct coupling or communication connection between the components shown or discussed may be through some interfaces, and the indirect coupling or communication connection between the devices or units may be electrical, mechanical or other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units; can be located in one place or distributed on a plurality of network units; some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, all the functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may be separately regarded as one unit, or two or more units may be integrated into one unit; the integrated unit can be realized in a form of hardware, or in a form of hardware plus a software functional unit.

Those of ordinary skill in the art will understand that: all or part of the steps for realizing the method embodiments can be completed by hardware related to program instructions, the program can be stored in a computer readable storage medium, and the program executes the steps comprising the method embodiments when executed; and the aforementioned storage medium includes: various media that can store program codes, such as a removable Memory device, a Read Only Memory (ROM), a magnetic disk, or an optical disk.

Alternatively, the integrated unit of the present invention may be stored in a computer-readable storage medium if it is implemented in the form of a software functional module and sold or used as a separate product. Based on such understanding, the technical solutions of the embodiments of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the methods described in the embodiments of the present invention. And the aforementioned storage medium includes: a removable storage device, a ROM, a magnetic or optical disk, or other various media that can store program code.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of changes or substitutions within the technical scope of the present invention, and all such changes or substitutions are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (33)

1. An information configuration method applied to a terminal is characterized by comprising the following steps:

receiving configuration information sent by network equipment;

determining a frequency point related to mobility management and/or a cell corresponding to the frequency point according to the configuration information and a network identifier of an operator to which the terminal belongs;

measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result;

and determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

2. The method of claim 1, wherein the mobility management comprises: cell reselection, network controlled mobility or handover.

3. The method of claim 1, wherein the frequency points comprise at least one of: different frequency points in the same system and different system frequency points.

4. The method of claim 1, wherein the determining, by the terminal, the frequency point and/or the cell corresponding to the frequency point related to mobility management comprises:

the terminal determines the network identifier of the operator from the memory or the SIM card, or the terminal determines the network identifier of the operator according to the IMSI;

and the terminal determines the frequency point information corresponding to the network identifier which is the same as the network identifier of the operator to which the terminal belongs in the configuration information as the frequency point related to the mobility management of the terminal and/or the cell corresponding to the frequency point according to the network identifier of the operator to which the terminal belongs.

5. The method of claim 1, wherein the configuration information comprises at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

6. The method of claim 5, wherein the configuration information comprises at least one of:

the first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information;

the second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information;

the third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point;

the fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

7. The method of claim 1, wherein the configuration information comprises at least one of:

the first configuration information comprises the pilot frequency point information and at least one network identifier corresponding to the pilot frequency point information;

the second configuration information comprises the inter-system frequency point information and at least one network identifier corresponding to the inter-system frequency point information;

the third configuration information comprises the pilot frequency point information and/or at least one network identifier corresponding to the pilot frequency point;

the fourth configuration information includes the inter-system frequency point information and/or at least one network identifier corresponding to the inter-system frequency point.

8. The method of claim 7, wherein the configuration information comprises at least one of:

when the first configuration information contains a network identifier corresponding to the pilot frequency point information, the first configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the second configuration information contains a network identifier corresponding to the inter-system frequency point information, the second configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the third configuration information contains a network identifier corresponding to the pilot frequency point information, the third configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

and when the fourth configuration information contains a network identifier corresponding to the inter-system frequency point information, the fourth configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment.

9. The method of claim 1, further comprising:

and receiving the configuration information sent by the network equipment through receiving a system message or a special message.

10. The method of claim 1, further comprising:

and when the receiving power or the receiving quality of the signal of the resident cell is smaller than a first preset threshold, starting cell reselection measurement, and measuring a frequency point or a cell corresponding to the frequency point, which is contained in the first configuration information and/or the second configuration information and is the same as the network identifier of the operator to which the terminal belongs, to obtain a measurement result.

11. The method of claim 10, further comprising: and when the measurement result is greater than a second preset threshold, reselecting the corresponding cell.

12. The method according to claim 1, wherein the measuring the frequency point and/or the cell corresponding to the frequency point to obtain the measurement result comprises: the terminal measures a frequency point or a cell corresponding to the frequency point which is the same as the network identifier of the operator to which the terminal belongs, and obtains a measurement result.

13. The method of claim 1, wherein the determining whether to perform cell reselection or report the measurement result to a network device according to the measurement result comprises: and when the terminal is in a connected state, the terminal reports the measurement result to the network equipment so that the network equipment determines whether the terminal needs to be switched.

14. The method of claim 10, wherein the cell signal comprises at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

15. An information configuration method applied to a network device, the method comprising:

sending configuration information to a terminal, wherein the configuration information comprises at least one of the following:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

and the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises different system frequency point information and/or network identification corresponding to the different system frequency point information.

16. The method of claim 15, wherein the configuration information comprises at least one of:

the first configuration information comprises the first pilot frequency point information and a first network identifier corresponding to the first pilot frequency point information, and second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point information; or

The second configuration information comprises the first different system frequency point information and a first network identifier corresponding to the first different system frequency point information, and second different system frequency point information and a second network identifier corresponding to the second different system frequency point information; or

The third configuration information comprises at least one of the first pilot frequency point information, a first network identifier corresponding to the first pilot frequency point, second pilot frequency point information and a second network identifier corresponding to the second pilot frequency point; or

The fourth configuration information includes at least one of the first inter-system frequency point information, the first network identifier corresponding to the first inter-system frequency point, the second inter-system frequency point information, and the second network identifier corresponding to the second inter-system frequency point.

17. The method of claim 15, further comprising: and configuring the configuration information according to the network sharing information.

18. The method of claim 17, wherein the network sharing information comprises: the first network identification and the corresponding pilot frequency point information and/or the different system frequency point information, and the second network identification and the corresponding pilot frequency point information and/or the different system frequency point information.

19. The method according to any of claims 16 to 18, wherein the first network identity is a network identity of an operator to which the network device belongs;

the second network identification is a network identification of an operator sharing the network device.

20. The method of claim 15, wherein the configuration information comprises at least one of:

the first configuration information comprises the pilot frequency point information and at least one network identifier corresponding to the pilot frequency point information;

the second configuration information comprises the inter-system frequency point information and at least one network identifier corresponding to the inter-system frequency point information;

the third configuration information comprises the pilot frequency point information and/or at least one network identifier corresponding to the pilot frequency point;

the fourth configuration information includes the inter-system frequency point information and/or at least one network identifier corresponding to the inter-system frequency point.

21. The method of claim 20, wherein the configuration information comprises at least one of:

when the first configuration information contains a network identifier corresponding to the pilot frequency point information, the first configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the second configuration information contains a network identifier corresponding to the inter-system frequency point information, the second configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

when the third configuration information contains a network identifier corresponding to the pilot frequency point information, the third configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment;

and when the fourth configuration information contains a network identifier corresponding to the inter-system frequency point information, the fourth configuration information contains a network identifier of an operator to which the network equipment belongs and at least one network identifier of an operator sharing the network equipment.

22. The method of claim 15, wherein the first configuration information is sent via a system message;

the second configuration information is sent via a system message;

the third configuration information is sent through an RRC message;

the fourth configuration information is transmitted through an RRC message.

23. The method of claim 15, further comprising:

receiving a measurement result of the receiving power or the receiving quality of at least one cell signal on the frequency point reported by the terminal;

and when the difference between the measurement result and a second measurement value obtained by measuring the receiving power or the receiving quality of the signal of the service cell by the terminal is larger than a preset third threshold, initiating a switching request to the cell corresponding to the measurement result.

24. The method of claim 23, wherein the cell signal comprises at least one of: downlink reference signals, pilot signals, synchronization signals, broadcast signals, channel state indication signals and SSBs of the cell.

25. The method of claim 15, further comprising:

determining home operator information of the terminal;

and determining configuration information for the terminal according to the home operator information of the terminal.

26. The method of claim 25, wherein the determining home operator information for the terminal comprises: and determining the home operator information of the terminal according to the IMSI identifier of the terminal.

27. The method of claim 25, wherein the determining the configuration information for the terminal according to the home operator information of the terminal comprises: and determining frequency point information corresponding to the network identifier of the home operator of the terminal as configuration information of the terminal according to the network identifier of the home operator of the terminal and the network sharing information.

28. The method according to any of claims 15 to 27, wherein the network identity is a public land mobile network identity.

29. The method of claim 25, wherein the network identifier is implicitly sent, comprising:

the network equipment determines a configuration information list, wherein each piece of information in the configuration information list corresponds to a specific network identifier; alternatively, the first and second electrodes may be,

and the network equipment segments the configuration information, and each segment corresponds to a specific network identifier.

30. An information configuring apparatus, the apparatus comprising:

a first receiving unit, configured to receive configuration information sent by a network device;

a first determining unit, configured to determine a frequency point and/or a cell corresponding to the frequency point related to mobility management according to the configuration information and a network identifier of an operator to which the terminal belongs;

the first measurement unit is used for measuring the frequency point and/or the cell corresponding to the frequency point to obtain a measurement result;

and the second determining unit is used for determining whether to perform cell reselection or report the measurement result to the network equipment according to the measurement result.

31. An information configuration device applied to a network device, the device comprising:

a third determining unit, configured to determine configuration information, where the configuration information includes at least one of:

the method comprises the steps that first configuration information related to pilot frequency cell reselection is obtained, wherein the first configuration information comprises pilot frequency point information and a network identifier corresponding to the pilot frequency point information;

second configuration information related to inter-system cell reselection, wherein the second configuration information comprises inter-system frequency point information and a network identifier corresponding to the inter-system frequency point information;

the network controls mobility or switches related third configuration information, wherein the third configuration information comprises pilot frequency point information and/or network identification corresponding to the pilot frequency point information;

the network controls mobility or switches related fourth configuration information, wherein the fourth configuration information comprises inter-system frequency point information and/or network identification corresponding to the frequency point;

and the sending unit is used for sending the configuration information to the terminal.

32. A computer device comprising a memory and a processor, the memory storing a computer program operable on the processor, wherein the processor implements the steps of the method of any one of claims 1 to 14 or 15 to 29 when executing the program.

33. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 14 or 15 to 29.

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