CN113312881A - Frequency band information conversion method and device, electronic equipment and computer storage medium - Google Patents

Abstract

The embodiment of the invention relates to the technical field of computers, and discloses a frequency band information conversion method and device, electronic equipment and a computer storage medium. The method comprises the following steps: acquiring target information needing to be converted into a code form, wherein the target information comprises frequency band combination information, input/output information and uplink frequency band information; dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information; and adding additional information of each sub-frequency band information obtained according to the target information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form, wherein the additional information specifically comprises channel information and identification information, and then connecting each sub-frequency band information in the code form through a connector to obtain the target information in the code form. According to the invention, the target information is obtained by using the electronic equipment, and is converted into the target information in a code form, so that the conversion efficiency and the conversion accuracy are greatly improved, and the debugging process of researchers is accelerated.

Description

Frequency band information conversion method and device, electronic equipment and computer storage medium

Technical Field

The embodiment of the invention relates to the technical field of computers, in particular to a frequency band information conversion method and device, electronic equipment and a computer storage medium.

Background

The 5G network refers to a fifth generation network in the development of mobile communication networks, and the 5G network will exhibit more enhanced functions in practical application compared with the previous four generation mobile communication networks, for example, theoretically, the transmission speed of the 5G network can reach tens of GB per second, which is about several hundred times of the transmission speed of the 4G mobile network.

Although the 5G network is powerful, considering that the cost of 5G SA (stand-alone networking) is too high, most operators at home and abroad choose to adopt NSA (Non-stand-alone networking) in the early stage, that is, adopt EN-DC (E-UTRA and New radio dual Connectivity, dual connection of 4G radio access network and 5G New air interface), that is, use a 4G core network, but the air interface includes two parts, namely 4G and 5G. The NSA needs to simultaneously transmit data by using a carrier corresponding to the 4G frequency band and a carrier corresponding to the 5G frequency band, the 4G frequency band and the 5G frequency band are both divided into a plurality of sub-frequency bands, and carrier aggregation can be further implemented by using a plurality of 4G sub-frequency bands obtained by dividing the 4G frequency band, that is, data transmission can be simultaneously performed by using carriers corresponding to a plurality of 4G sub-frequency bands, so as to increase the data transmission bandwidth of the system. If a part of 4G sub-bands in the plurality of 4G sub-bands obtained by dividing the 4G band are first subjected to carrier aggregation and then are arranged and combined with a plurality of 5G sub-bands obtained by dividing the 5G band, a plurality of EN-DC combinations can be obtained, for example, there is one EN-DC combination: the data transmission method comprises the following steps that DC _1A-3A-41C-42C _ n257A, wherein 1A, 3A, 41C and 42C are four 4G sub-bands obtained by dividing a 4G frequency band, n257A is a 5G sub-band obtained by dividing a 5G frequency band, and the four 4G sub-bands and the 5G sub-band need to transmit data simultaneously.

Because the number of the 4G sub-bands and the 5G sub-bands is large, and carrier aggregation can be performed between the 4G sub-bands, tens of thousands of EN-DC combinations can be obtained after permutation and combination, and the performance of data transmission performed simultaneously by each sub-band included in one EN-DC combination often has a certain difference with the performance of data transmission performed simultaneously by each sub-band included in another EN-DC combination, so that researchers are required to debug the tens of thousands of EN-DC combinations one by one to obtain the transmission performance of each EN-DC combination and to better apply the EN-DC combinations to transmit data subsequently. Researchers typically debug these EN-DC combinations through software, which requires converting a row of table containing EN-DC combinations such as "DC _1A-3A-41C-42C _ n 257A" and a row of band information in the form of TXT or a row of table specifying Multiple Input Multiple Output (MIMO) bands, Single Input Single Output (SISO) bands, and an EN-DC combination of upstream bands in the EN-DC combination into code in the form of XML (xtensible Markup language), which is a set of specifications created by internet federation, in order to help software developers and content creators organize and transfer information through a network.

Referring to table 1 and table 2, in table 1, a row of tables of EN-DC combinations are illustrated by the EN-DC combination "DC _1A-3A-41C-42C _ n 257A", 4G 4 × 4MIMO bands are 1A-3A-41C bands, 4G uplink bands are 1A bands, and 5G uplink SISO bands are n257A bands, and a row of tables of EN-DC combinations are illustrated by the EN-DC combination "DC _1A-3A-41C-42C _ n 257A", 4G 4 × 4MIMO bands are 1A-3A-41C bands, 4G uplink bands are 1A bands, and 5G uplink 2 × 2 bands are n257A bands.

TABLE 1 one-line Table of EN-DC combinations

TABLE 2 Another row Table for EN-DC combinations

At present, each line table of different EN-DC combinations is converted into an XML-form code by manpower, the number of EN-DC combinations is quite large, the conversion efficiency of manual conversion is low, the debugging process of the EN-DC combinations can be seriously influenced, the XML-form code has strict requirements, the compiling is failed due to any symbol input error, and the debugging process of researchers on the EN-DC combinations can be further influenced due to the low accuracy of the manual conversion.

Disclosure of Invention

Embodiments of the present invention provide a frequency band information conversion method and apparatus, an electronic device, and a computer storage medium, which can improve efficiency and accuracy of converting EN-DC combined information in a table format into EN-DC combined information in a code format, so as to accelerate a debugging process.

In order to solve the above technical problem, an embodiment of the present invention provides a frequency band information conversion method, including the following steps: acquiring target information needing to be converted into a code form; the target information comprises frequency band combination information, input/output information and uplink frequency band information; dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information; adding additional information of each sub-frequency band information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form; the additional information is obtained according to the target information, and comprises channel information and identification information for distinguishing different network modes; and connecting the information of each sub-frequency band in the code form through a connector to obtain the target information in the code form.

The embodiment of the present invention further provides a frequency band information conversion apparatus, including: the device comprises an acquisition module, a dividing module, a conversion module and a connection module; the acquisition module is used for acquiring target information needing to be converted into a code form; the target information comprises frequency band combination information, input/output information and uplink frequency band information; the division module is used for dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information; the conversion module is used for adding additional information of each sub-frequency band information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form; the additional information is obtained according to the target information, and comprises channel information and identification information for distinguishing different network modes; the connection module is used for connecting the information of each sub-frequency band in the code form through a connector to obtain the target information in the code form.

An embodiment of the present invention further provides an electronic device, including: at least one processor; and a memory communicatively coupled to the at least one processor; the memory stores instructions executable by the at least one processor, and the instructions are executed by the at least one processor to enable the at least one processor to execute the frequency band information conversion method.

The embodiment of the invention also provides a computer readable storage medium, which stores a computer program, and the computer program is executed by a processor to realize the frequency band information conversion method.

Compared with the related art, the electronic equipment acquires target information (including frequency band combination information, input/output information and uplink frequency band information) which needs to be converted into a code form, divides the frequency band combination information according to separators contained in the frequency band combination information to obtain a plurality of pieces of sub-frequency band information, obtains additional information of each piece of sub-frequency band information, including channel information and identification information used for distinguishing different network systems, on the basis of each piece of sub-frequency band information, adds corresponding additional information to obtain each piece of sub-frequency band information in the code form, and connects the pieces of sub-frequency band information in the code form through connectors to obtain the target information in the code form. The invention utilizes the electronic equipment to automatically acquire the target information, converts the target information into the target information in a code form according to the information such as the frequency band combination information, the input/output information, the uplink frequency band information and the like included in the target information, can greatly improve the conversion efficiency and the conversion accuracy rate, further accelerates the debugging process of researchers, and can also distinguish the sub-frequency band information of different network modes according to the identification information in the additional information in the target information in the code form.

In addition, after obtaining the information of the plurality of sub-bands, the method further includes: matching each sub-frequency band information with the uplink frequency band information; and adding uplink information into the additional information of the successfully matched sub-frequency band information, wherein the uplink information is obtained according to the successfully matched sub-frequency band information. In this embodiment, uplink information may be used to distinguish uplink/downlink sub-band information.

In addition, the method for obtaining each sub-band information in a code form by adding additional information of each sub-band information on the basis of each sub-band information comprises the following steps: adding identification information in front of each sub-frequency band information; adding channel information behind each sub-frequency band information; and adding the uplink information behind the channel information of the sub-frequency band information belonging to the uplink frequency band information to obtain each sub-frequency band information in a code form. In this embodiment, a specific position of the identification information, the channel information, and the uplink information before and after the sub-band information is provided, and a specific form of the sub-band information in the form of a code is presented.

In addition, after the frequency band combination information is divided according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information, the method further comprises the following steps: acquiring identification information of each sub-frequency band information according to whether the marker is included in the sub-frequency band information or not; the identification information of the sub-band information containing the marker and the identification information of the sub-band information not containing the marker are different.

In addition, after the frequency band combination information is divided according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information, the method further comprises the following steps: acquiring a bandwidth model included in each sub-frequency band information; acquiring the channel number of each sub-frequency band information according to the bandwidth model; and acquiring the number of selectable antennas of each sub-band information according to the input and output information, and acquiring the channel information of each sub-band information according to the number of channels and the number of selectable antennas.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the figures in which like reference numerals refer to similar elements and which are not to scale unless otherwise specified.

Fig. 1 is a flowchart of a frequency band information conversion method according to an embodiment of the present invention;

fig. 2 is a flowchart of a frequency band information conversion method including a manner of acquiring uplink information according to an embodiment of the present invention;

fig. 3 is a flowchart of a frequency band information conversion method including a manner of acquiring identification information according to an embodiment of the present invention;

fig. 4 is a flowchart of a frequency band information conversion method including a manner of acquiring communication information according to an embodiment of the present invention;

fig. 5 is a flowchart of a frequency band information conversion method including a manner of acquiring each sub-band information (additional information includes only identification information and channel information) in the form of a code according to an embodiment of the present invention;

fig. 6 is a flowchart of a frequency band information conversion method including a manner of acquiring each sub-band information (additional information includes identification information, channel information, and uplink information) in the form of a code according to an embodiment of the present invention;

fig. 7 is a flowchart of a frequency band information conversion method according to another embodiment of the present invention;

fig. 8 is a block diagram of a frequency band information conversion apparatus according to an embodiment of the present invention;

fig. 9 is a block diagram of a frequency band information converting apparatus according to another embodiment of the present invention;

FIG. 10 is a block schematic diagram of an electronic device of one embodiment of the invention.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in various embodiments of the invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solution claimed in the present application can be implemented without these technical details and various changes and modifications based on the following embodiments. The following embodiments are divided for convenience of description, and should not constitute any limitation to the specific implementation manner of the present invention, and the embodiments may be mutually incorporated and referred to without contradiction.

One embodiment of the present invention relates to a frequency band information conversion method for converting a table of a plurality of EN-DC combinations obtained due to non-independent networking into an XML-format code, so that a researcher can further analyze the transmission performance of each of the EN-DC combinations through the converted XML-format code.

A specific flow of the frequency band information conversion method of this embodiment is shown in fig. 1.

Step 101, acquiring target information including frequency band combination information, input/output information and uplink frequency band information, which needs to be converted into a code form.

And 102, dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information.

And 103, adding additional information of each sub-band information acquired according to the target information on the basis of each sub-band information to obtain each sub-band information in a code form.

And 104, connecting the information of each sub-frequency band in the code form through a connector to obtain target information in the code form.

In this embodiment, after acquiring target information (including frequency band combination information, input/output information, and uplink frequency band information) that needs to be converted into a code form, the electronic device divides the frequency band combination information according to separators included in the frequency band combination information to obtain a plurality of pieces of sub-frequency band information, obtains additional information of each piece of sub-frequency band information including channel information and identification information for distinguishing different network systems according to the target information, adds corresponding additional information on the basis of each piece of sub-frequency band information to obtain each piece of sub-frequency band information in the code form, and connects the pieces of sub-frequency band information in the code form through a connector to obtain the target information in the code form. The invention utilizes the electronic equipment to automatically acquire the target information, converts the target information into the target information in a code form according to the information such as the frequency band combination information, the input/output information, the uplink frequency band information and the like included in the target information, can greatly improve the conversion efficiency and the conversion accuracy rate, further accelerates the debugging process of researchers, and can also distinguish the sub-frequency band information of different network modes according to the identification information in the additional information in the target information in the code form.

Specifically, the present application may obtain target information that needs to be converted into a code format, where the target information is, for example, an original table shown in table 3 below, and at this time, the frequency band combination information is "DC _1A-3A-41C-42C _ n 257A" corresponding to "EN-DC combination", the input and output information includes "1A-3A-41C, 1A-3A-42C" corresponding to "4G 4 × 4MIMO frequency band", "n 257A" corresponding to "5G uplink SISO frequency band", and "n 257A" corresponding to "5G uplink 2 × 2MIMO frequency band", and the uplink frequency band information is "1A, 3A" corresponding to "4G uplink frequency band".

The electronic device first performs permutation and combination on the contents that can be permutated and combined in the original table to obtain an expanded table with multiple rows of EN-DC combinations, and please refer to tables 4 to 11, where the original table can expand an obtained table with 8 rows of EN-DC combinations. In the second column of the original table are "1A-3A-41C, 1A-3A-42C", i.e. 1A-3A-41C or 1A-3A-42C can be selected as the 4G 4 x 4MIMO band, where there are 2 options; in the third column of the original table, "1A, 3A", that is, the 1A frequency band or the 3A frequency band may be selected as the 4G uplink frequency band, where there are 2; in the fourth column of the original table, "n 257A", that is, the n257A frequency band may be selected as the uplink SISO (single input single output) frequency band of 5G; the fifth column of the original table is "n 257A", that is, the n257A band can be selected as the 5G uplink 2 × 2MIMO (multiple input multiple output) band, it should be noted that, for the n257A band, only the 5G uplink SISO (single input single output) band can be selected at the same time, or the 5G uplink 2 × 2MIMO (multiple input multiple output) band cannot be used as both the MIMO band and the SISO band, so there are 2 choices for the n257A band. In summary, there are 2 alternative forms for the 4G 4 × 4MIMO band, the 4G uplink band and the n257A band, so the original table in table 3 can be expanded by permutation and combination to obtain a table of 2 × 2 — 8 EN-DC combinations.

The expanded row of the EN-DC combined table can be converted into one XML form of code, and one row of the original table corresponds to eight XML forms of code in total.

TABLE 3 original Table of EN-DC combinations

TABLE 4 expanded EN-DC COMBINATION TABLE (1)

TABLE 5 expanded EN-DC COMBINATION TABLE (2)

TABLE 6 expanded EN-DC COMBINATION TABLE (3)

TABLE 7 expanded EN-DC COMBINATION TABLE (4)

TABLE 8 expanded EN-DC COMBINATIONS TABLE (5)

TABLE 9 expanded EN-DC COMBINATION TABLE (6)

TABLE 10 expanded EN-DC COMBINATION TABLE (7)

TABLE 11 expanded EN-DC COMBINATIONS TABLE (8)

The electronic equipment converts the expanded table of each line of EN-DC combination into data in a TXT form, converts the frequency band information in the TXT form into a two-dimensional array form, and can show the corresponding relation between the content of each grid in the table of the EN-DC combination and the specific position of the grid in the whole table through the two-dimensional array form.

After the data in the two-dimensional array form is converted, the electronic equipment searches whether a row of two-dimensional arrays containing two-dimensional arrays with the number smaller than a preset threshold exists, if the number of the two-dimensional arrays contained in the row of two-dimensional arrays is smaller than the preset threshold, the codes in the XML form obtained through conversion are definitely wrong, and therefore if the row of two-dimensional arrays containing the number smaller than the preset threshold exists, the row of two-dimensional arrays is deleted.

After deleting each row of two-dimensional arrays containing the two-dimensional arrays with the number smaller than a preset threshold value, acquiring frequency band combination information by electronic equipment, wherein the frequency band combination information is, for example, 'DC _1A-3A-41C-42C _ n 257A', dividing the frequency band combination information according to separators in the frequency band combination information, the separators can be '_' and 'minus', acquiring a plurality of sub-frequency band information, adding additional information of each sub-frequency band information on the basis of each sub-frequency band information, and acquiring each sub-frequency band information in a code form, wherein the additional information is acquired according to target information, the additional information comprises channel information and identification information for distinguishing network systems, for example, 4G and 5G frequency bands can be distinguished by using the identification information, and finally connecting each sub-frequency band information in the code form through connectors, and acquiring the target information in the code form, in one embodiment, the connector may be "+".

In an embodiment, step 201, step 202, step 205, and step 206 are substantially the same as step 101, step 102, step 103, and step 104, and are not described herein again, and the embodiment corresponding to fig. 1 is different in that step 203 is further included.

A specific flow of the frequency band information conversion method of this embodiment is shown in fig. 2.

Step 203, matching each sub-band information with the uplink band information.

And step 204, adding uplink information in the additional information of the successfully matched sub-frequency band information.

Specifically, after obtaining the multiple pieces of sub-band information, the electronic device needs to match each piece of sub-band information with the uplink-band information, specifically, whether each piece of sub-band information is consistent with the uplink-band information needs to be matched, if the matching is successful, the uplink information is added to the additional information of the successfully-matched sub-band information, and the uplink information is specifically obtained according to the successfully-matched sub-band information. For example, if the uplink frequency band information is "1A", it is known that the sub-frequency band information "1A" is the sub-frequency band information successfully matched with the uplink frequency band information "1A", the uplink information needs to be added to the additional information of the sub-frequency band information "1A", and the uplink information of the sub-frequency band information "1A" is, for example; a [1] ", wherein"; "to identify that the sub-band information belongs to the uplink band information.

In an embodiment, step 301, step 302, step 304, and step 305 are substantially the same as step 101, step 102, step 103, and step 104, and are not described herein again, and the embodiment corresponding to fig. 1 is different in that step 303 is further included.

A specific flow of the frequency band information conversion method of this embodiment is shown in fig. 3.

Step 303, obtaining the identification information of each sub-band information according to whether each sub-band information contains a marker.

Specifically, the electronic device may divide the sub-band information belonging to different network systems according to whether each sub-band information includes a marker, for example, divide each sub-band information into two types, i.e., 4G sub-band information and 5G sub-band information. For example, there is the following sub-band information: "1A", "3A", "41C", "42C", and "n 257A", at this time, the marker is considered as "n", and if "n" is not included, the marker is divided into 4G sub-band information; if the data includes "n", the data is divided into 5G sub-band information. According to the above division rule, "1A", "3A", "41C", "42C" is divided into 4G sub-band information, and "n 257A" is divided into 5G sub-band information. For the 4G sub-band information and the 5G sub-band information, different identification information is obtained to distinguish the two information, for example, the identification information uses "B" to identify the 4G sub-band information, and uses "N" to identify the 5G sub-band information.

In an embodiment, step 401, step 402, step 406, and step 407 are substantially the same as step 101, step 102, step 103, and step 104, and are not repeated herein, and the embodiment corresponding to fig. 1 is different in that step 403, step 404, and step 405 are further included.

A specific flow of the frequency band information conversion method of this embodiment is shown in fig. 4.

Step 403, acquiring the bandwidth model included in each sub-band information, and acquiring the number of channels of each sub-band information according to the bandwidth model.

Specifically, the electronic device obtains the bandwidth model included in each piece of sub-band information, for example, "a" in the sub-band information "1A" is the bandwidth model, "C" in the sub-band information "41C" is also the bandwidth model, what is the channel number in the channel information of each piece of sub-band information is obtained according to the bandwidth model, the bandwidth model and the channel number have a preset corresponding relationship, the channel number corresponding to the bandwidth model "a" is 1, "the channel number corresponding to the B" is 2, "the channel number corresponding to the C" is 2, "the channel number corresponding to the D" is 3, "the channel number corresponding to the E" is 4, "the channel number corresponding to the F" is 5, "the channel number corresponding to the G" is 2, "the channel number corresponding to the H" is 3, "the channel number corresponding to the I" is 4, "the channel number corresponding to the J" is 5, "the channel number corresponding to the K" is 6, the number of channels corresponding to "L" is 7, the number of channels corresponding to "M" is 8, the number of channels corresponding to "O" is 3, the number of channels corresponding to "P" is 4, and the number of channels corresponding to "Q" is 5.

And step 404, acquiring the number of selectable antennas of each sub-band information according to the input and output information.

Specifically, the electronic device may obtain, according to the obtained input/output information, the number of selectable antennas in the channel information of each sub-band information, where for example, the input/output information includes: the 4G 4 × 4MIMO band is "1A-3A-41C", and for the band combination information "DC _1A-3A-41C-42C _ n 257A", the "42C" is not the 4G 4 × 4MIMO band, so that the "1A", "3A" and "41C" are divided into 4G 4 × 4MIMO subband information, and the "42C" is divided into 4G SISO subband information. For 4G SISO subband information, the number of selectable antennas of each channel of the subband information is only 1, and for 4G 4 × 4MIMO subband information, the number of selectable antennas of each channel of the subband information is 4. For 5G sub-band information, if a sub-band information is divided into 5G SISO sub-band information, the number of selectable antennas of each channel of the sub-band information is only 1; if a sub-band information is divided into 5G 2 x 2MIMO sub-band information, the number of selectable antennas of each channel of the sub-band information is 2.

Step 405, obtaining the channel information of each sub-band information according to the number of channels and the number of selectable antennas.

For example, if the input/output information includes: 4G 4 × 4MIMO band is "1A-3A-41C", then for the sub-band information "1A", the number of channels is 1, the number of selectable antennas is 4, and the channel information is "[ 4 ]"; for the sub-band information "41C", the number of channels is 2, the number of selectable antennas is 4, and the channel information is "[ 4,4 ]". It can be seen that the number of channels determines the dimension of the channel information, i.e. the number of selectable antennas per channel in the channel information.

It should be noted that, in this embodiment, the order of executing step 403 and step 404 is not limited, that is, the number of channels of each sub-band information may be obtained first, or the number of selectable antennas of each sub-band information may be obtained first, and in this embodiment, step 403 is executed first, and then step 404 is executed as an example.

In one embodiment, step 501, step 502, and step 504 are substantially the same as step 101, step 102, and step 104, and are not described herein again.

The specific flow of the frequency band information conversion method of this embodiment is shown in fig. 5, and step 503 includes the following sub-steps.

Sub-step 5031, adding identification information in front of each sub-band information.

Sub-step 5032, adding channel information behind each sub-band information to obtain each sub-band information in a code form.

It is noted that sub-step 5031 may be performed after sub-step 5032.

In an embodiment, step 601, step 602, step 603, step 604, and step 606 are substantially the same as step 201, step 202, step 203, step 204, and step 206, and are not repeated herein.

The specific flow of the frequency band information conversion method of this embodiment is shown in fig. 6, and step 605 includes the following sub-steps.

In sub-step 6051, identification information is added in front of each sub-band information.

Sub-step 6052 adds channel information after each sub-band information.

Substep 6053, add uplink information after the channel information of the successfully matched sub-band information to obtain each sub-band information in code form.

It should be noted that sub-step 6052 and sub-step 6053 have a requirement of a fixed sequence, and the electronic device needs to add channel information first and then add uplink information after channel information of successfully matched sub-band information, and when this sequence is satisfied, sub-step 6051 may also occur after sub-step 6052 or sub-step 6053.

In this embodiment, after acquiring target information (including frequency band combination information, input/output information, and uplink frequency band information) that needs to be converted into a code form, the electronic device divides the frequency band combination information according to separators included in the frequency band combination information to obtain a plurality of pieces of sub-frequency band information, and obtains additional information of each piece of sub-frequency band information, including channel information and identification information for distinguishing different network systems, according to the target information, where the additional information of the piece of sub-frequency band information that is successfully matched with the uplink frequency band information also includes the uplink information, adds corresponding additional information to each piece of sub-frequency band information to obtain each piece of sub-frequency band information in the code form, and connects the pieces of sub-frequency band information in the code form through connectors to obtain the target information in the code form.

Referring to fig. 7, fig. 7 is a diagram illustrating that, on the basis of the embodiment corresponding to fig. 1, uplink information of sub-band information successfully matched with the uplink frequency band information is acquired by the frequency band information conversion method of the embodiment corresponding to fig. 2, identification information of each sub-band information is acquired by the frequency band information conversion method of the embodiment corresponding to fig. 3, channel information of each sub-band information is acquired by the frequency band information conversion method of the embodiment corresponding to fig. 4, and each sub-band information is converted into each sub-band information in a code form by the frequency band information conversion method of the embodiment corresponding to fig. 6.

Step 701, acquiring target information including frequency band combination information, input/output information and uplink frequency band information, which needs to be converted into a code form.

Step 702, dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information.

Step 703, obtaining the identification information of each sub-band information according to whether each sub-band information contains a marker.

Step 704, obtaining the bandwidth model included in each sub-band information, and obtaining the channel number of each sub-band information according to the bandwidth model.

Step 705, obtaining the number of selectable antennas of each sub-band information according to the input and output information.

Step 706, obtaining the channel information of each sub-band information according to the number of channels and the number of selectable antennas.

And step 707, matching each sub-band information with the uplink frequency band information, and adding the uplink information to the additional information of the successfully matched sub-band information.

And 708, adding additional information of each sub-band information acquired according to the target information on the basis of each sub-band information to obtain each sub-band information in a code form.

And 709, connecting the information of each sub-frequency band in the code form through a connector to obtain target information in the code form.

Wherein step 708 further comprises sub-step 7081, sub-step 7082 and sub-step 7083.

And a substep 7081 of adding identification information in front of each subband information.

Sub-step 7082, adding channel information after each sub-band information.

And a substep 7083 of adding uplink information after the channel information of the successfully matched sub-band information to obtain each sub-band information in a code form.

In this embodiment, except that step 706 must be performed after step 704 and step 705, the sequence of step 703 to step 707 is not limited, that is, the sequence of obtaining the identification information, the channel information, and the uplink information of each sub-band information is not limited.

The following description will take the example of converting table 4 into a code in XML format.

The frequency band combination information acquired by the electronic device is "DC _1A-3A-41C-42C _ n 257A", and the "DC _1A-3A-41C-42C _ n 257A" is divided according to separators "_" and "-", so as to obtain several parts of "DC", "1A", "3A", "41C", "42C" and "n 257A", where "1A", "3A", "41C", "42C" and "n 257A" are frequency sub-band information, and "DC" only represents that the frequency band combination information is a double-connection combination including a 4G frequency band and a 5G frequency band, and does not belong to the frequency sub-band information.

After obtaining these pieces of sub-band information, "1A", "3A", "41C", and "42C" do not include the marker "N", and thus these pieces of sub-band information are divided into 4G sub-band information, "N257A" includes the marker "N", so "N257A" is divided into 5G sub-band information, "B" is added in front of the 4G sub-band information, and "N" is added in front of the 5G sub-band information from which the marker is deleted, and "B1A", "B3A", "B41C", "B42C", and "N257A" can be obtained.

The input and output information acquired by the electronic equipment respectively comprises: "1A-3A-41C" is 4G 4 × 4MIMO band, "n 257A" is 5G uplink SISO band, which can be further obtained according to the information, "42C" not mentioned in 4G 4 × 4MIMO band is 4G SISO band, and the default "n 257A" 5G downlink band is 2 × 2MIMO band.

For 'B1A', the bandwidth model is 'a', the number of channels corresponding to the bandwidth model is 1, and '1A' belongs to a 4G 4 x 4MIMO band, the number of selectable antennas of each channel is 4, channel information '1A [4 ]' of '1A' can be obtained, and the channel information is combined with the identification information to obtain 'B1A [4 ]'; "B3A [4 ]", "B41C [4,4 ]" and "B42C [2,2 ]", can be obtained by subjecting "B3A", "B41C" and "B42C" to the same treatment as "B1A".

The processing for "N257A" is slightly different from the processing for "B1A", in that, for the 5G sub-band information, the number of selectable antennas of each channel is incremented by a multiple of 100, for example, "N257A" is a 5G uplink SISO band, the number of selectable antennas of each channel corresponding to "N257A" is 100, for example, "N257A" is a 5G uplink 2 × 2MIMO band, the number of selectable antennas of each channel corresponding to "N257A" is 100 × 2 ═ 200, when the number of selectable antennas is indicated in square brackets, "100X 1" is required to indicate that the number of selectable antennas is 100, and "100X 2" is required to indicate that the number of selectable antennas is 200. Since the default "N257A" of 5G downlink frequency band is 2 × 2MIMO frequency band, the "N257A [100X2 ]" can be obtained after processing "N257A".

The uplink frequency band information acquired by the electronic device includes: "1A" is 4G uplink frequency band, "n 257A" is 5G uplink SISO frequency band, so the additional information of the sub-band information "1A" and the sub-band information "n 257A" includes uplink information, and the uplink information of "1A" is specifically; the uplink information of A [1] "," n257A "is specifically; a [100X1] ". Wherein, "; "is used to identify that the sub-band information belongs to the uplink band information; the bandwidth model in the uplink information of the sub-band information is often consistent with the bandwidth model of the sub-band information, so the bandwidth model in the uplink information of "1A" is also "a", the number of channels corresponding to the bandwidth model is also 1, the number of selectable antennas of each channel of the default 4G uplink frequency band is 1, and the number of selectable antennas of each channel corresponding to the 5G uplink SISO frequency band is 100.

On the basis of "B1A [4 ]", "B3A [4 ]", "B41C [4,4 ]", "B42C [2,2 ]" and "N257A [100X2 ]", the uplink information is added after the channel information of the sub-band information belonging to the uplink band information, and each sub-band information in the form of a code can be obtained: "B1A [4 ]; a [1] "," B3A [4] "," B41C [4,4] "," B42C [2,2] "and" N257A [100X2 ]; a [100X1] ".

And finally, connecting the information of each sub-frequency band in the code form through a connector '+' to obtain the target information in the code form: "B1A [4 ]; a [1] + B3A [4] + B41C [4,4] + B42C [2,2] + N257A [100X2 ]; a [100X1] ".

The following description will take the example of converting table 5 into XML format code.

Table 5 differs from table 4 only in that "n 257A" is no longer a 5G uplink SISO band, but is a 5G uplink 2 × 2MIMO band, and since this change is only related to the uplink information of the 5G sub-band information, in order to avoid redundancy, only the change of the uplink information of the 5G sub-band information is described herein. Since the number of selectable antennas of each channel corresponding to the 5G uplink 2 × 2MIMO band is 200, in the square bracket of the uplink information of the 5G sub-band information, "100X 2" is needed to indicate that the number of selectable antennas is 200, and the uplink information is added in "N257A [100X2 ]" to obtain the sub-band information in the form of codes: "N257A [100X2 ]; a [100X2] ", therefore, the target information in the form of codes in table 5 is:

“B1A[4]；A[1]+B3A[4]+B41C[4,4]+B42C[2,2]+N257A[100X2]；A[100X2]”。

in this embodiment, after acquiring target information (including frequency band combination information, input/output information, and uplink frequency band information) that needs to be converted into a code form, the electronic device divides the frequency band combination information according to separators included in the frequency band combination information to obtain a plurality of pieces of sub-frequency band information, and obtains additional information of each piece of sub-frequency band information, including channel information and identification information for distinguishing different network systems, according to the target information, where the additional information of the piece of sub-frequency band information that belongs to the uplink frequency band information also includes the uplink information, adds corresponding additional information to each piece of sub-frequency band information to obtain each piece of sub-frequency band information in the code form, and connects the pieces of sub-frequency band information in the code form through connectors to obtain the target information in the code form.

The steps of the above methods are divided for clarity, and the implementation may be combined into one step or split some steps, and the steps are divided into multiple steps, so long as the same logical relationship is included, which are all within the protection scope of the present patent; it is within the scope of the patent to add insignificant modifications to the algorithms or processes or to introduce insignificant design changes to the core design without changing the algorithms or processes.

An embodiment of the present invention relates to a frequency band information conversion apparatus, please refer to fig. 8, which includes: the device comprises an acquisition module 1, a dividing module 2, a conversion module 3 and a connection module 4.

Firstly, acquiring target information needing to be converted into a code form by an acquisition module 1; the target information comprises frequency band combination information, input/output information and uplink frequency band information, the division module 2 divides the frequency band combination information according to separators in the frequency band combination information to obtain a plurality of sub-frequency band information, the conversion module 3 adds additional information of each sub-frequency band information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form, wherein the additional information is obtained according to the target information, the additional information specifically comprises channel information and identification information used for distinguishing different network modes, and finally the connection module 4 connects each sub-frequency band information in the code form through connectors to obtain the target information in the code form.

It should be understood that this embodiment is a system embodiment corresponding to the embodiment shown in fig. 1, and this embodiment can be implemented in cooperation with the embodiment shown in fig. 1. The related technical details mentioned in the embodiment corresponding to fig. 1 are still valid in this embodiment, and are not described herein again in order to reduce repetition. Accordingly, the related art details mentioned in the present embodiment can also be applied to the embodiment corresponding to fig. 1.

It should be noted that, all the modules involved in this embodiment are logic modules, and in practical application, one logic unit may be one physical unit, may also be a part of one physical unit, and may also be implemented by a combination of multiple physical units. In addition, in order to highlight the innovative part of the present invention, a unit which is not so closely related to solve the technical problem proposed by the present invention is not introduced in the present embodiment, but this does not indicate that there is no other unit in the present embodiment.

An embodiment of the present invention relates to a frequency band information conversion apparatus, please refer to fig. 9, which further includes a matching module 5, wherein the matching module 5 is connected between the dividing module 2 and the converting module 3.

The matching module 5 matches the information of each sub-band with the information of the uplink frequency band, and adds the uplink information to the additional information of the successfully matched sub-band information, wherein the uplink information is obtained according to the successfully matched sub-band information.

The conversion module 3 will add identification information in front of each sub-band information, add channel information behind each sub-band information, and add uplink information behind the channel information of the successfully matched sub-band information to obtain each sub-band information in the form of codes.

In an embodiment, the obtaining module 1 may obtain the identification information of each sub-band information according to whether each sub-band information includes a marker, and specifically, may divide each sub-band information into two types, i.e., 4G sub-band information and 5G sub-band information according to whether each sub-band information includes a marker, and adopt different identification information for the 4G sub-band information and the 5G sub-band information, respectively, to distinguish the 4G sub-band information from the 5G sub-band information.

The obtaining module 1 may further obtain a bandwidth model included in each sub-band information, obtain the number of channels of each sub-band information according to the bandwidth model, obtain the number of selectable antennas of each sub-band information according to the input/output information, and obtain the channel information of each sub-band information according to the number of channels and the number of selectable antennas.

Specifically, after the obtaining module 1 obtains the input/output information, each piece of sub-band information may be divided into two types, i.e., an MIMO sub-band and an SISO sub-band, according to the input/output information, and different selectable antenna numbers are used for the MIMO sub-band and the SISO sub-band.

Since the embodiments corresponding to fig. 2 to fig. 6 correspond to the present embodiment, the present embodiment can be implemented in cooperation with the embodiments corresponding to fig. 2 to fig. 6. The related technical details mentioned in the embodiments corresponding to fig. 2 to 6 are still valid in this embodiment, and the technical effects achieved in the embodiments corresponding to fig. 2 to 6 can also be achieved in this embodiment, and are not described herein again in order to reduce repetition. Accordingly, the related art details mentioned in the present embodiment can also be applied to the embodiments corresponding to fig. 2 to 6.

One embodiment of the invention relates to an electronic device, as shown in fig. 10, comprising at least one processor 1001; and memory 1002 communicatively coupled to the at least one processor 1001; the memory 1002 stores instructions executable by the at least one processor 1001, and the instructions are executed by the at least one processor 1001, so that the at least one processor 1001 can execute the frequency band information conversion method in the foregoing embodiments.

Where the memory and processor are connected by a bus, the bus may comprise any number of interconnected buses and bridges, the buses connecting together one or more of the various circuits of the processor and the memory. The bus may also connect various other circuits such as peripherals, voltage regulators, power management circuits, and the like, which are well known in the art, and therefore, will not be described any further herein. A bus interface provides an interface between the bus and the transceiver. The transceiver may be one element or a plurality of elements, such as a plurality of receivers and transmitters, providing a means for communicating with various other apparatus over a transmission medium. The data processed by the processor is transmitted over a wireless medium via an antenna, which further receives the data and transmits the data to the processor.

The processor is responsible for managing the bus and general processing and may also provide various functions including timing, peripheral interfaces, voltage regulation, power management, and other control functions. And the memory may be used to store data used by the processor in performing operations.

One embodiment of the present invention relates to a computer-readable storage medium storing a computer program. The computer program, when executed by the processor, implements the frequency band information conversion method in the above-described embodiments.

That is, as can be understood by those skilled in the art, all or part of the steps in the method for implementing the embodiments described above may be implemented by a program instructing related hardware, where the program is stored in a storage medium and includes several instructions to enable a device (which may be a single chip, a chip, or the like) or a processor (processor) to execute all or part of the steps of the method described in the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

It will be understood by those of ordinary skill in the art that the foregoing embodiments are specific embodiments for practicing the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in practice.

Claims (10)

1. A frequency band information conversion method is characterized by comprising the following steps:

acquiring target information needing to be converted into a code form; the target information comprises frequency band combination information, input/output information and uplink frequency band information;

dividing the frequency band combination information according to separators in the frequency band combination information to obtain a plurality of sub-frequency band information;

adding additional information of each sub-frequency band information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form; the additional information is obtained according to the target information, and comprises channel information and identification information for distinguishing different network modes;

and connecting the information of each sub-frequency band in the code form through a connector to obtain the target information in the code form.

2. The method for converting frequency band information according to claim 1, wherein after obtaining the plurality of sub-band information, the method further comprises:

matching each sub-frequency band information with the uplink frequency band information;

and adding uplink information in the additional information of the successfully matched sub-frequency band information, wherein the uplink information is obtained according to the successfully matched sub-frequency band information.

3. The method of claim 2, wherein the adding additional information of each sub-band information on the basis of each sub-band information to obtain each sub-band information in a code form comprises:

adding the identification information in front of each sub-frequency band information;

adding the channel information behind each sub-frequency band information;

and adding the uplink information behind the channel information of the successfully matched sub-frequency band information to obtain each sub-frequency band information in a code form.

4. The method for converting frequency band information according to any one of claims 1 to 3, wherein after the dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information, the method further comprises:

acquiring the identification information of each sub-frequency band information according to whether the sub-frequency band information contains a marker or not;

wherein the sub-band information including the marker and the identification information of the sub-band information not including the marker are different.

5. The method for converting frequency band information according to claim 4, wherein after the dividing the frequency band combination information according to the separators in the frequency band combination information to obtain a plurality of sub-frequency band information, the method further comprises:

acquiring a bandwidth model included in each sub-frequency band information;

acquiring the channel number of each sub-frequency band information according to the bandwidth model;

acquiring the number of selectable antennas of each sub-frequency band information according to the input and output information;

and acquiring the channel information of each sub-frequency band information according to the number of the channels and the number of the selectable antennas.

6. A frequency band information converting apparatus, comprising: the device comprises an acquisition module, a dividing module, a conversion module and a connection module;

the acquisition module is used for acquiring target information needing to be converted into a code form; the target information comprises frequency band combination information, input/output information and uplink frequency band information;

the dividing module is used for dividing the frequency band combination information according to separators in the frequency band combination information to obtain a plurality of sub-frequency band information;

the conversion module is used for adding additional information of each sub-frequency band information on the basis of each sub-frequency band information to obtain each sub-frequency band information in a code form; the additional information is obtained according to the target information, and comprises channel information and identification information for distinguishing different network modes;

the connection module is used for connecting the sub-frequency band information in the code form through a connector to obtain the target information in the code form.

7. The frequency band information converting apparatus according to claim 6, further comprising a matching module;

the matching module is used for matching each sub-frequency band information with the uplink frequency band information, and adding uplink information into the additional information of the successfully matched sub-frequency band information, wherein the uplink information is obtained according to the successfully matched sub-frequency band information;

the conversion module is specifically configured to add the identification information in front of each piece of the sub-band information, add the channel information behind each piece of the sub-band information, and add the uplink information behind the channel information of the successfully matched sub-band information, so as to obtain each piece of the sub-band information in a code form.

8. The frequency band information converting apparatus according to claim 6 or 7,

the obtaining module is further configured to obtain the identification information of each sub-band information according to whether each sub-band information includes a marker; wherein the sub-band information including the marker and the identification information of the sub-band information not including the marker are different;

the acquisition module is further configured to acquire, after acquiring a bandwidth model included in each piece of sub-band information, a channel number of each piece of sub-band information according to the bandwidth model, acquire an optional antenna number of each piece of sub-band information according to the input/output information, and acquire the channel information of each piece of sub-band information according to the channel number and the optional antenna number.

9. An electronic device, comprising:

at least one processor; and the number of the first and second groups,

a memory communicatively coupled to the at least one processor; wherein,

the memory stores instructions executable by the at least one processor to enable the at least one processor to perform the frequency band information converting method of any one of claims 1 to 5.

10. A computer-readable storage medium storing a computer program, wherein the computer program is executed by a processor to implement the frequency band information converting method according to any one of claims 1 to 5.

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