CN110035515B

CN110035515B - Resource allocation method and device, storage medium and processor

Info

Publication number: CN110035515B
Application number: CN201810032037.0A
Authority: CN
Inventors: 任敏; 夏树强; 田力; 韩祥辉; 石靖; 林伟
Original assignee: ZTE Corp
Current assignee: ZTE Corp
Priority date: 2018-01-12
Filing date: 2018-01-12
Publication date: 2024-02-27
Anticipated expiration: 2038-01-12
Also published as: WO2019137447A1; CN110035515A

Abstract

The invention provides a resource allocation method and device, a storage medium and a processor, wherein the method comprises the following steps: determining time domain frequency domain locations of a plurality of transmission opportunities from at least one of the following: resource allocation information, redundancy version information; the method solves the problem that the time domain and frequency domain positions of the repeated transmission opportunities cannot be determined by combining the resource allocation information and the redundancy version information in the related technology, and achieves the effect of determining the time domain and frequency domain positions of the repeated transmission opportunities by combining the resource allocation information and the redundancy version information.

Description

Resource allocation method and device, storage medium and processor

Technical Field

The present invention relates to the field of communications, and in particular, to a resource allocation method and apparatus, a storage medium, and a processor.

Background

The standard formulation work of the first stage of the fifth generation mobile communication technology (5G,the 5th Generation mobile communication technology) is completed. From the trend of standard formulation and technology development, 5G systems are dedicated to research on technical indexes such as higher rate (Gbps), huge amount of links (1M/Km 2), ultra-low time delay (1 ms), higher reliability, hundred times of energy efficiency improvement and the like to support new demand changes.

In order to support the characteristics of ultra-high reliability and ultra-low delay transmission, the transmission of the low-delay and high-reliability service in a shorter transmission time is completed, and the uplink and the downlink are required to be enhanced. In particular, in uplink, after the terminal sends the scheduling request, the terminal can receive the uplink authorization information of the base station at a certain interval, and then can send corresponding uplink data at a certain interval. Therefore, in order to meet the requirement of ultra-low delay transmission of the uplink, an uplink unlicensed transmission mode (physical downlink shared channel Physical UplinkShared Channel, abbreviated as PUSCH) is proposed in the 5G stage, and in order to meet the characteristic of high reliability, a method for repeatedly transmitting the same uplink data for multiple times is also proposed. Currently, in the uplink unlicensed multiple repeat transmission technology, the configuration relationship between the resource location of the first transmission and the three redundancy version (Redundancy Version, abbreviated as RV) sequences has been determined, and in order to obtain the frequency diversity gain, how to hop frequencies in the frequency domain within the time slots (slots) has also been determined.

Aiming at the problem that the time domain and frequency domain positions of multiple repeated transmission opportunities can not be determined by combining the resource allocation information and the redundancy version information in the related technology, no effective solution has been proposed.

Disclosure of Invention

The embodiment of the invention provides a resource allocation method and device, a storage medium and a processor, which at least solve the problem that the time domain and frequency domain positions of repeated transmission opportunities can not be determined by combining resource allocation information and redundancy version information in the related technology.

According to an embodiment of the present invention, there is provided a resource allocation method including:

determining time domain frequency domain locations of a plurality of transmission opportunities from at least one of the following: resource allocation information, redundancy version information.

Optionally, the time domain frequency domain positions of the plurality of transmission opportunities are used periodically, and each period has K transmission opportunities of the same transmission block, where K is a positive integer.

Optionally, the resource allocation information indicates a time domain frequency domain location of the first transmission opportunity.

Optionally, the value of K is indicated by at least one of: first higher layer signaling, first physical layer signaling;

the redundancy version information is indicated by at least one of: first high layer signaling, first physical layer signaling, second high layer signaling, second physical layer signaling. .

Optionally, the time domain frequency domain location is configured by at least one of: higher layer signaling, physical layer signaling.

Optionally, the redundancy version information = { a, a, a, a }, where a is taken from the set {0,1,2,3}, and K is greater than or equal to 2, and determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities includes:

the frequency domain positions of all the odd transmission opportunities corresponding to the resources are the same or the frequency domain positions of part or all of the odd transmission opportunities corresponding to the resources are inserted with a fixed offset, the frequency domain positions of all the even transmission opportunities corresponding to the resources are the same or the frequency domain positions of part or all of the even transmission opportunities corresponding to the resources are inserted with a fixed offset, and the frequency domain positions of the odd transmission opportunities corresponding to the resources are different from the frequency domain positions of the even transmission opportunities corresponding to the resources.

Optionally, the offset size of the frequency domain position of the resource corresponding to the odd transmission opportunity and the frequency domain position corresponding to the even transmission opportunity is signaled by a higher layer; the fixed deviation is predefined.

Optionally, the RV sequence= { a, b, a, b }, where the a and b are each taken from the set {0,1,2,3}, and the a and b are different in value, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities includes:

The frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are different Representing a rounding up operation.

Optionally, offset magnitudes of the frequency domain positions of the resources corresponding to 4m+1,4m+2 transmission opportunities and the frequency domain positions of the resources corresponding to 4m+3,4m+4 transmission opportunities are signaled by a higher layer. The fixed deviation is predefined.

Optionally, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity in the K transmission opportunities further includes:

the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 4m+2,4m+3 transmission opportunities are the same or the frequency domain positions of the 4m+2,4m+3 transmission opportunities are inserted with a fixed offset, and the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources Representing a rounding upAnd (3) operating.

Optionally, the offset size of the frequency domain position of the 4m+1 th transmission opportunity corresponding resource and the frequency domain position of the 4m+2,4m+3 th transmission opportunity corresponding resource is signaled by a high layer, and the offset size of the frequency domain position of the 4m+2,4m+3 th transmission opportunity corresponding resource and the frequency domain position of the 4m+4 th transmission opportunity corresponding resource is signaled by a high layer; the fixed deviation is predefined.

Optionally, the redundancy version information = { a, b, c, d }, where a, b, c, d is taken from the set {0,1,2,3}, and the values of a, b, c, d are different, and when K is greater than or equal to 4, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity in the K transmission opportunities includes:

the frequency domain positions of the 8 < th > m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8 < m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunity corresponding resources are different from the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 > transmission opportunity corresponding resources, wherein Representing a rounding up operation.

Optionally, offset magnitudes of the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities and the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are signaled by a higher layer. The fixed deviation is predefined.

Optionally, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities further includes:

8m+1,8m+2,8m+5,8mThe frequency domain positions of the +6 transmission opportunity corresponding resources are the same or the frequency domain positions of the 8m+1,8m+2,8m+5,8m+6 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8m+3,8m+4,8m+7,8m+8 transmission opportunity corresponding resources are the same or the frequency domain positions of the 8m+3,8m+4,8m+7,8m+8 transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8m+1,8m+2,8m+5,8m+6 transmission opportunity corresponding resources are different from the frequency domain positions of the 8m+3,8m+4,8m+7,8m+8 transmission opportunity corresponding resources, wherein Representing a rounding up operation.

Optionally, the offset magnitudes of the frequency domain positions of the resources corresponding to the 8m+1,8m+2 transmission opportunities and the frequency domain positions of the resources corresponding to the 8m+3,8m+4 transmission opportunities are signaled by a high layer, and the offset magnitudes of the frequency domain positions of the resources corresponding to the 8m+5,8m+6 transmission opportunities and the frequency domain positions of the resources corresponding to the 8m+7,8m+8 transmission opportunities are signaled by a high layer; the fixed deviation is predefined.

Optionally, when K is greater than or equal to 8, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities includes:

the frequency domain positions of the 8 < th > m+1,8 < 2 >, 8 < m+3 >, 8 < m+4 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < th > m+1,8 < m+2 >, 8 < m+3 >, 8 < m+4 > transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8 < th > m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunity corresponding resources are different from the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 > transmission opportunity corresponding resources, wherein Representing a rounding up operation.

Optionally, when K is greater than or equal to 4 and less than 8, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities further includes:

the frequency domain positions of the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8 < m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resources are different from the frequency domain positions of the 8 < m+3,8 < m+4,8 < m+7,8 > transmission opportunity corresponding resources, said Representing a rounding up operation.

According to another embodiment of the present invention, there is provided a resource allocation method including:

transmitting at least one of the following objects to the terminal: and the resource allocation information and the redundancy version information are used for enabling the terminal to determine the time domain and frequency domain positions of a plurality of transmission opportunities.

Optionally, the time domain frequency domain positions of the plurality of transmission opportunities are used in periods, each period has K transmission opportunities of the same transmission block, and K is a positive integer.

Optionally, the resource allocation information indicates a time domain, frequency domain position of the first transmission opportunity.

the redundancy version information is indicated by at least one of: first high layer signaling, first physical layer signaling, second high layer signaling, second physical layer signaling.

Optionally, the offset size of the frequency domain position of the resource corresponding to the odd transmission opportunity and the frequency domain position corresponding to the even transmission opportunity is signaled by a higher layer.

Optionally, the redundancy version information = { a, b, a, b }, where the a and b are each taken from the set {0,1,2,3}, and the a and b are different in value, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities includes:

Optionally, offset magnitudes of the frequency domain positions of the resources corresponding to 4m+1,4m+2 transmission opportunities and the frequency domain positions of the resources corresponding to 4m+3,4m+4 transmission opportunities are signaled by a higher layer.

the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 4m+2,4m+3 transmission opportunities are the same or the frequency domain positions of the 4m+2,4m+3 transmission opportunities are inserted, and the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources Representing a rounding up operation.

the frequency domain positions of the 8 < m > -1, 8 < m > -2, 8 < m > -5, 8 < m > -6 transmission opportunity corresponding resources are identical or the frequency domain positions of the 8 < m > -1, 8 < m > -2, 8 < m > -5, 8 < m > -6 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8 < m > -3, 8 < m > -4, 8 < m > -7, 8 < m > -8 transmission opportunity corresponding resources are identical or the frequency domain positions of the 8 < m > -1, 8 < m > -2, 8 < m > -5, 8 < m > -6 transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8 < m > -1, 8 < m > -2, 8 < m > -5, 8 < m > -6 transmission opportunity corresponding resources are different from the frequency domain positions of the 8 < m > -3, 8 < m > -4, 8 < m > -7, 8 < m > -8 transmission opportunity corresponding resources, wherein Representing a rounding up operation.

Optionally, the offset magnitudes of the frequency domain positions of the resources corresponding to the 8m+1,8m+2 transmission opportunities and the frequency domain positions of the resources corresponding to the 8m+3,8m+4 transmission opportunities are signaled by a high layer, and the offset magnitudes of the frequency domain positions of the resources corresponding to the 8m+5,8m+6 transmission opportunities and the frequency domain positions of the resources corresponding to the 8m+7,8m+8 transmission opportunities are signaled by a high layer. The fixed deviation is predefined.

the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7,8m+8 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7 The frequency domain position of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resource is inserted with a fixed offset, and the frequency domain position of the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resource is different from the frequency domain position of the 8 < m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunity corresponding resource, said Representing a rounding up operation.

According to another embodiment of the present invention, there is also provided a resource allocation apparatus, applied to a terminal, including:

a determining module for determining time domain frequency domain positions of a plurality of transmission opportunities according to at least one of the following objects: resource allocation information, redundancy version information.

According to another embodiment of the present invention, there is also provided a resource allocation apparatus applied to a base station, including:

a transmitting module, configured to transmit at least one of the following objects to a terminal: and the resource allocation information and the redundancy version information are used for enabling the terminal to determine the time domain and frequency domain positions of a plurality of transmission opportunities.

According to another embodiment of the present invention, there is also provided a storage medium including a stored program, wherein the program, when run, performs the method of any one of the above.

According to another embodiment of the present invention, there is also provided a processor for running a program, wherein the program, when run, performs the method of any one of the above.

According to the invention, the terminal can determine the time domain and frequency domain positions of a plurality of transmission opportunities according to at least one of the resource allocation information and the redundancy version information; therefore, the method and the device can solve the problem that the time domain and frequency domain positions of the repeated transmission opportunities cannot be determined by combining the resource allocation information and the redundancy version information in the related technology, and achieve the effect of determining the time domain and frequency domain positions of the repeated transmission opportunities by combining the resource allocation information and the redundancy version information.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

FIG. 1 is a flowchart (one) of a resource allocation method provided according to an embodiment of the present invention;

FIG. 2 is a flowchart (II) of a resource allocation method according to an embodiment of the present invention;

FIG. 3 is a block diagram (I) of a resource allocation apparatus according to an embodiment of the present invention;

FIG. 4 is a block diagram (II) of a resource allocation apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic illustration of a first preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 6 is a schematic diagram (one) of a second preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 7 is a schematic diagram (II) of a second preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 8 is a schematic diagram (III) of a second preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 9 is a schematic diagram (fourth) of a second preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 10 is a schematic diagram (fifth) of a second preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 11 is a schematic illustration (one) of a third preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 12 is a schematic illustration (II) of a third preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 13 is a schematic illustration (III) of a preferred embodiment III provided in accordance with an embodiment of the present invention;

FIG. 14 is a schematic view (IV) of a third preferred embodiment provided in accordance with an embodiment of the invention;

FIG. 15 is a schematic view (fifth) of a third preferred embodiment provided in accordance with an embodiment of the present invention;

FIG. 16 is a schematic illustration (six) of a preferred embodiment III provided in accordance with an embodiment of the present invention;

FIG. 17 is a schematic illustration (seventh) of a preferred embodiment III provided in accordance with an embodiment of the present invention;

fig. 18 is a schematic view (eight) of a third preferred embodiment provided in accordance with an embodiment of the present invention.

Detailed Description

The invention will be described in detail hereinafter with reference to the drawings in conjunction with embodiments. It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present invention and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order.

Example 1

In this embodiment, a resource allocation method is provided, fig. 1 is a flowchart (a) of the resource allocation method provided according to an embodiment of the present invention, and as shown in fig. 1, the method includes:

s100, determining time domain and frequency domain positions of a plurality of transmission opportunities according to at least one of the following objects: resource allocation information, redundancy version information.

the frequency domain positions of the resources corresponding to 4m+1,4m+2 transmission opportunities are the same or the 4m+1,4m+2 transmission opportunities correspondThe frequency domain position of the resource is inserted with a fixed offset, the frequency domain position of the resource corresponding to 4m+3,4m+4 transmission opportunities is the same or the frequency domain position of the resource corresponding to 4m+3,4m+4 transmission opportunities is inserted with a fixed offset, and the frequency domain position of the resource corresponding to 4m+1,4m+2 transmission opportunities is different from the frequency domain position of the resource corresponding to 4m+3,4m+4 transmission opportunities, wherein the frequency domain positions of the resource corresponding to 4m+1,4m+2 transmission opportunities are different from the frequency domain position of the resource corresponding to 4m+3,4m+4 transmission opportunities Representing a rounding up operation.

the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 4m+2,4m+3 transmission opportunities are the same or the frequency domain positions of the 4m+2,4m+3 transmission opportunities are inserted with a fixed offset, and the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+1,4m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+2,4m+3 transmission opportunity corresponding resources Representing a rounding up operation.

the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7,8m+8 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 8m+3 The frequency domain positions of the resources corresponding to the 8m+4,8m+7,8m+8 transmission opportunities are inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7,8m+8 transmission opportunities, wherein the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 8m+3 Representing a rounding up operation.

From the description of the above embodiments, it will be clear to a person skilled in the art that the method according to the above embodiments may be implemented by means of software plus the necessary general hardware platform, but of course also by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) comprising several instructions for causing a terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) to perform the method of the various embodiments of the present invention.

Example 2

According to another embodiment of the present invention, there is provided a resource allocation method, and fig. 2 is a flowchart (second) of the resource allocation method provided according to an embodiment of the present invention, as shown in fig. 2, where the method includes:

s200, at least one of the following objects is sent to the terminal: and the resource allocation information and the redundancy version information are used for enabling the terminal to determine the time domain and frequency domain positions of a plurality of transmission opportunities.

By the method of the embodiment of the invention, the base station can send at least one of the following objects to the terminal: resource allocation information and redundancy version information, so that the terminal determines time domain and frequency domain positions of a plurality of transmission opportunities; therefore, the method and the device can solve the problem that the time domain and frequency domain positions of the repeated transmission opportunities cannot be determined by combining the resource allocation information and the redundancy version information in the related technology, and achieve the effect of determining the time domain and frequency domain positions of the repeated transmission opportunities by combining the resource allocation information and the redundancy version information.

the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are inserted with a fixed offset, and the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are the same or the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are the sameThe frequency domain positions are the same, and the frequency domain positions of the resources corresponding to 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to 4m+2,4m+3 transmission opportunities, wherein the frequency domain positions of the resources corresponding to 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to 4m+2,4m+3 transmission opportunities Representing a rounding up operation.

the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are the same or the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are inserted with a fixed offset, 8The frequency domain positions of the m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources are the same or the frequency domain positions of the 8m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8m+1,8m+2,8m+3,8m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 8m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources, wherein the method comprises the steps of Representing a rounding up operation.

the frequency domain positions of the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are inserted with a fixed offset, the frequency domain positions of the 8 < m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are the same or the frequency domain positions of the 8 < m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunity corresponding resources are inserted with a fixed offset, and the frequency domain positions of the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunity corresponding resources are different from the frequency domain positions of the 8 < m+3,8 < m+4,8 < m+7,8 > transmission opportunity corresponding resources, said Representing a rounding up operation.

Example 3

According to another embodiment of the present invention, a resource allocation device is further provided, and the device is used for implementing the foregoing embodiments and preferred embodiments, and will not be described again. As used below, the term "module" may be a combination of software and/or hardware that implements a predetermined function. While the means described in the following embodiments are preferably implemented in software, implementation in hardware, or a combination of software and hardware, is also possible and contemplated. Fig. 3 is a block diagram (a) of a resource allocation device according to an embodiment of the present invention, and as shown in fig. 3, the device includes:

a determining module 100, configured to determine time domain frequency domain positions of a plurality of transmission opportunities according to at least one of the following objects: resource allocation information, redundancy version information.

By the device of the embodiment of the invention, the terminal can determine the time domain and frequency domain positions of a plurality of transmission opportunities according to at least one of the resource allocation information and the redundancy version information; therefore, the method and the device can solve the problem that the time domain and frequency domain positions of the repeated transmission opportunities cannot be determined by combining the resource allocation information and the redundancy version information in the related technology, and achieve the effect of determining the time domain and frequency domain positions of the repeated transmission opportunities by combining the resource allocation information and the redundancy version information.

Optionally, the time domain frequency domain positions of the plurality of transmission opportunities are used periodically, and each period corresponds to K transmission opportunities of the same transmission block, where K is a positive integer.

Optionally, the resource allocation information indicates time domain frequency domain resources of the first transmission opportunity.

Optionally, the time domain frequency domain resources are configured by at least one of: higher layer signaling, physical layer signaling.

Optionally, the redundancy version information = { a, a, a, a }, where a is taken from the set {0,1,2,3}, K is greater than or equal to 2, and determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises:

It should be noted that each of the above modules may be implemented by software or hardware, and for the latter, it may be implemented by, but not limited to: the modules are all located in the same processor; alternatively, the above modules may be located in different processors in any combination.

Example 4

The embodiment of the present invention provides a resource allocation device, which is used to implement the foregoing embodiments and preferred embodiments, and is not described in detail. As used below, the term "module" may be a combination of software and/or hardware that implements a predetermined function. While the means described in the following embodiments are preferably implemented in software, implementation in hardware, or a combination of software and hardware, is also possible and contemplated. Fig. 4 is a block diagram (two) of a resource allocation apparatus according to an embodiment of the present invention, and as shown in fig. 4, the apparatus includes:

a transmitting module 200, configured to transmit at least one of the following objects to a terminal: and the resource allocation information and the redundancy version information are used for enabling the terminal to determine the time domain and frequency domain positions of a plurality of transmission opportunities.

By the device provided by the embodiment of the invention, the base station can send at least one of the following objects to the terminal: resource allocation information and redundancy version information, so that the terminal determines time domain and frequency domain positions of a plurality of transmission opportunities; therefore, the method and the device can solve the problem that the time domain and frequency domain positions of the repeated transmission opportunities cannot be determined by combining the resource allocation information and the redundancy version information in the related technology, and achieve the effect of determining the time domain and frequency domain positions of the repeated transmission opportunities by combining the resource allocation information and the redundancy version information.

Optionally, the time domain frequency domain positions of the plurality of transmission opportunities are used periodically, each period corresponds to K transmission opportunities of the same transmission block, and K is a positive integer.

The technical solution in the present invention is further explained by the preferred embodiments below:

preferred embodiment 1

When the configured RV sequence= {0, 0}, the number of transmission opportunities K > = 2, and frequency hopping is enabled, then the frequency domain positions corresponding to the two consecutive transmission opportunities are different.

Or equivalently, the frequency domain positions of all the resources corresponding to the odd transmission opportunities are the same or the frequency domain positions of part or all of the resources corresponding to the odd transmission opportunities are inserted with a fixed offset, and the frequency domain positions of all the resources corresponding to the even transmission opportunities are the same or the frequency domain positions of part or all of the resources corresponding to the even transmission opportunities are inserted with a fixed offset. I.e. the frequency domain position of the resource corresponding to the odd transmission opportunity is different from the frequency domain position of the resource corresponding to the even transmission opportunity.

When RV sequence= {0, 0}, transmission opportunity k=8, and the corresponding resource allocation method is shown in fig. 5.

By means of the resource allocation method of the RV sequence = {0, 0} in the preferred embodiment, as long as the first transmission starts at the next to last transmission opportunity, the frequency diversity gain can be obtained, so that the reliability of data transmission is improved.

Preferred embodiment 2

When the configured RV sequence= {0,3,0,3}, and frequency hopping is enabled, the time domain frequency domain location method of K transmission opportunities of the same transport block may be one of the following two.

Method 1: the frequency domain positions of the resources corresponding to 4m+1,4m+2 transmission opportunities are the same or partially or fully inserted with a fixed offset, and the frequency domain positions corresponding to 4m+3,4m+4 transmission opportunities are the same or partially or fully inserted with a fixed offset. That is, the frequency domain positions of the resources corresponding to 4m+1,4m+2 transmission opportunities are different from those of the resources corresponding to 4m+3,4m+4 transmission opportunities. And the repetition number K > =2.

Wherein,

for example, when the number of transmission opportunities k=4, m=0 can be obtained according to the above formula. Then the frequency domain locations of the corresponding resources for transmission opportunities 1 and 2 are the same or a fixed offset is inserted in part or in whole. The frequency domain locations of the 3 rd and 4 th transmission opportunity corresponding resources are the same or partially or fully inserted with a fixed offset, as shown in fig. 6.

When the number of transmission opportunities k=5 times, m=0 and 1 can be obtained according to the above formula. Then the frequency domain locations of the corresponding resources for transmission opportunities 1, 2 and 5 are the same or are partially or fully inserted with a fixed offset. The frequency domain positions of the corresponding resources of the 3 rd and 4 th transmission opportunities are the same or are partially or fully inserted with a fixed offset, as shown in fig. 7.

When the number of transmission opportunities k=8, m=0 and 1 can be obtained according to the above formula, and then the frequency domain positions of the corresponding resources of the 1 st, 2 nd, 5 th and 6 th transmission opportunities are the same or a fixed offset is partially or fully inserted. The frequency domain positions of the resources corresponding to the 3 rd, 4 th, 7 th and 8 th transmission opportunities are the same or are partially or completely inserted with a fixed offset, as shown in fig. 8.

Method 2: the frequency domain positions of the resources corresponding to 4m+1,4m+4 transmission opportunities are the same or partially or fully inserted with a fixed offset, and the frequency domain positions corresponding to 4m+2,4m+3 transmission opportunities are the same or partially or fully inserted with a fixed offset. That is, the frequency domain positions of the resources corresponding to 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to 4m+2,4m+3 transmission opportunities. And the repetition number K > =2.

Wherein,

for example, when the number of transmission opportunities k=4, m=0 can be obtained according to the above formula. Then the frequency domain locations of the corresponding resources for transmission opportunities 1 and 4 are the same or a fixed offset is inserted in part or in whole. The frequency domain positions of the corresponding resources of the 2 nd and 3 rd transmission opportunities are the same or are partially or fully inserted with a fixed offset, as shown in fig. 9.

The beneficial effects are that: in the manner of fig. 9, when the first transmission of the transport block is on the 3 rd transmission opportunity, frequency hopping can also be implemented by two consecutive transmissions, and frequency diversity gain is obtained.

When the number of transmission opportunities k=8, m=0 and 1 can be obtained according to the above formula, and then the frequency domain positions of the corresponding resources of the 1 st, 4 th, 5 th and 8 th transmission opportunities are the same or a fixed offset is partially or fully inserted. The frequency domain positions of the corresponding resources of the 2 nd, 3 rd, 6 th and 7 th transmission opportunities are the same or are partially or fully inserted with a fixed offset, as shown in fig. 10.

Considering that when uplink data is sent at different frequency domain positions, the transmission period of power on/off is subjected to one time, so that by means of the resource allocation method of RV sequence = {0,3,0,3} of the embodiment, not only the time loss of frequent on of the transmission period of power on/off can be reduced, but also pilot frequency sharing can be realized for every two transmission opportunities to reduce resource overhead.

Example 3

When the configured RV sequence= {0,2,3,1}, and frequency hopping is enabled, the time domain frequency domain location method of repeating transmission opportunity K times may be one of the following three methods.

Method 1: the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are the same or partially or fully inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are the same or partially or fully inserted with a fixed offset.

Alternatively, the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities.

Wherein,

for example, when the number of transmission opportunities k=8, m=0 can be obtained according to the above formula. Then the 1 st, 2 nd, 3 rd and 4 th transmission opportunities correspond to the same frequency domain location of the resource or are partially or fully inserted with a fixed offset. The frequency domain positions of the resources corresponding to the 5 th, 6 th, 7 th and 8 th transmission opportunities are the same or are partially or fully inserted with a fixed offset, as shown in fig. 11.

When the number of transmission opportunities k=12, m=0, 1 can be obtained according to the above formula. Then the frequency domain positions of the resources corresponding to the 1 st, 2 nd, 3 rd, 4 th, 9 th, 10 th, 11 th and 12 th transmission opportunities are the same or a fixed offset is partially or fully inserted. The frequency domain positions of the resources corresponding to the 5 th, 6 th, 7 th and 8 th transmission opportunities are the same or are partially or fully inserted with a fixed offset, as shown in fig. 12.

Method 2: the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are the same or partially or fully inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7,8m+8 transmission opportunities are the same or partially or fully inserted with a fixed offset. That is, the frequency domain positions of the resources corresponding to 8m+1,8m+2,8m+5,8m+6 transmission opportunities are different from those of the resources corresponding to 8m+3,8m+4,8m+7,8m+8 transmission opportunities.

Wherein,/>

for example, when the number of transmission opportunities k=4, m=0 can be obtained according to the above formula. Then the frequency domain locations of the corresponding resources for transmission opportunities 1 and 2 are the same or a fixed offset is inserted in part or in whole. The frequency domain positions of the corresponding resources of the 3 rd and 4 th transmission opportunities are the same or a fixed offset is partially or fully inserted. As shown in fig. 13.

When the number of transmission opportunities k=6, m=0 can be obtained according to the above formula. Then the 1 st, 2 nd, 5 th and 6 th transmission opportunities correspond to the same frequency domain location of the resource or are partially or fully inserted with a fixed offset. The frequency domain positions of the corresponding resources of the 3 rd and 4 th transmission opportunities are the same or a fixed offset is partially or fully inserted. As shown in fig. 14.

When the number of transmission opportunities k=7, m=0 can be obtained according to the above formula. Then the 1 st, 2 nd, 5 th and 6 th transmission opportunities correspond to the same frequency domain location of the resource or are partially or fully inserted with a fixed offset. The frequency domain positions of the resources corresponding to the 3 rd, 4 th and 7 th transmission opportunities are the same or are partially or completely inserted with a fixed offset. As shown in fig. 15.

Preferred embodiment 4

When there is a physical random access channel PRACH signal transmitted at the time domain position of the second transmission opportunity, the frequency domain position occupied by the PRACH is a predefined fixed value, so that the frequency hopping range of the second transmission opportunity is the sum of the frequency hopping offset (frequency offset) configured by the higher layer and the frequency domain size offset1 occupied by the PRACH.

The PRACH signal is not received on the fourth, sixth and eighth transmission opportunities, so the frequency hopping range is the frequency hopping offset size.

Of course, for RV {0,3,0,3} and rv= {0,2,3,1} there may be some transmission opportunity where the PRACH signal is received, so on this transmission opportunity, if the frequency is hopped, the frequency hopping range is the sum of the frequency hopping offset of the higher layer configuration and the frequency domain size offset1 occupied by the PRACH. As shown in fig. 18.

Method 3: when the number of transmission opportunities K > =8, method 1 is adopted; when 4< = K <8, method 2 is employed.

For example, when the number of transmission opportunities k=16, m=0, 1 can be obtained according to the above formula. Then the frequency domain positions of the resources corresponding to the 1 st, 2 nd, 3 rd, 4 th, 9 th, 10 th, 11 th and 12 th transmission opportunities are the same or a fixed offset is partially or fully inserted. The frequency domain positions of the resources corresponding to the 5 th, 6 th, 7 th, 8 th, 13 th, 14 th, 15 th and 16 th transmission opportunities are the same or a fixed offset is partially or fully inserted. As shown in fig. 16.

When the number of transmission opportunities k=5, m=0 can be obtained according to the above formula. Then the frequency domain locations of the corresponding resources for the 1 st, 2 nd and 5 th transmission opportunities are the same or are partially or fully inserted with a fixed offset. The frequency domain positions of the resources corresponding to the 3 rd and 4 th transmission opportunities are the same or partially or completely inserted with a fixed offset, as shown in fig. 17.

Considering that the uplink data is transmitted at different frequency domain positions, the transmission period of power on/off is experienced once, so by the resource allocation method of RV sequence = {0,2,3,1} of the embodiment, not only the time loss of frequent start of the transmission period of power on/off can be reduced, but also the pilot frequency sharing can be realized to reduce the resource overhead.

Example 5

According to another embodiment of the present invention, there is provided a storage medium including a stored program, wherein the program, when run, performs the method of any one of the above.

Alternatively, in the present embodiment, the storage medium may include, but is not limited to: a usb disk, a Read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing a computer program.

Example 6

According to another embodiment of the present invention, there is provided a processor for running a program, wherein the program when run performs the method of any one of the above.

Alternatively, specific examples in this embodiment may refer to examples described in the foregoing embodiments and optional implementations, and this embodiment is not described herein.

It will be appreciated by those skilled in the art that the modules or steps of the invention described above may be implemented in a general purpose computing device, they may be concentrated on a single computing device, or distributed across a network of computing devices, they may alternatively be implemented in program code executable by computing devices, so that they may be stored in a memory device for execution by computing devices, and in some cases, the steps shown or described may be performed in a different order than that shown or described, or they may be separately fabricated into individual integrated circuit modules, or multiple modules or steps within them may be fabricated into a single integrated circuit module for implementation. Thus, the present invention is not limited to any specific combination of hardware and software.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A method for resource allocation, comprising:

determining time domain frequency domain locations of a plurality of transmission opportunities from at least one of the following: the method comprises the steps of resource allocation information and redundancy version information, wherein time domain and frequency domain positions of a plurality of transmission opportunities are used periodically, each period has K transmission opportunities of the same transmission block, and K is a positive integer; the value of K is indicated by at least one of the following: first higher layer signaling, first physical layer signaling; the resource allocation information indicates a time domain frequency domain position of a first transmission opportunity; the redundancy version information is indicated by at least one of: a first high layer signaling, a first physical layer signaling, a second high layer signaling, a second physical layer signaling;

the redundancy version information = { a, a, a, a }, wherein the a is taken from the set {0,1,2,3}, the K is greater than or equal to 2, and determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises: the frequency domain positions of all the odd transmission opportunities corresponding to the resources are the same or the frequency domain positions of part or all of the odd transmission opportunities corresponding to the resources are inserted with a fixed offset, the frequency domain positions of all the even transmission opportunities corresponding to the resources are the same or the frequency domain positions of part or all of the even transmission opportunities corresponding to the resources are inserted with a fixed offset, and the frequency domain positions of the odd transmission opportunities corresponding to the resources are different from the frequency domain positions of the even transmission opportunities corresponding to the resources;

The redundancy version information = { a, b, a, b }, wherein the a and b are all taken from the set {0,1,2,3}, and the a and b are different in value, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises: the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, and the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resourcesRepresenting a rounding up operation.

2. The method of claim 1, wherein the step of determining the position of the substrate comprises,

the offset size of the frequency domain position of the resource corresponding to the odd transmission opportunity and the frequency domain position corresponding to the even transmission opportunity is notified by a high-layer signaling; the fixed offset size is predefined.

3. The method of claim 1, wherein offset magnitudes of the frequency domain locations of the resources corresponding to the 4m+1,4m+2 th transmission opportunities and the frequency domain locations of the resources corresponding to the 4m+3,4m+4 th transmission opportunities are signaled by a higher layer; the fixed offset size is predefined.

4. The method of claim 1, wherein determining the time domain frequency domain locations of the remaining K-1 transmission opportunities based on the time domain frequency domain location of the first of the K transmission opportunities further comprises:

the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are partially or completely inserted with a fixed deviation, the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are the same, or the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are partially or completely inserted with a fixed deviation, and the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 4m+2,4m+3 transmission opportunities, wherein the frequency domain positions of the resources corresponding to the 4m+2,4m+3 transmission opportunities are differentRepresenting a rounding up operation.

5. The method of claim 4, wherein the step of determining the position of the first electrode is performed,

the offset size of the frequency domain position of the 4m+1 transmission opportunity corresponding resource and the frequency domain position of the 4m+2,4m+3 transmission opportunity corresponding resource is notified by the high-level signaling, and the offset size of the frequency domain position of the 4m+2,4m+3 transmission opportunity corresponding resource and the frequency domain position of the 4m+4 transmission opportunity corresponding resource is notified by the high-level signaling;

The fixed offset size is predefined.

6. The method of claim 1, wherein the redundancy version information = { a, b, c, d }, the a, b, c, d is taken from a set {0,1,2,3}, and the a, b, c, d values are different, and when the K is greater than or equal to 4, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises:

the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are partially or completely inserted into oneThe frequency domain positions of the 8m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 8m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources are partially or completely inserted into one fixed deviation, and the frequency domain positions of the 8m+1,8m+2,8m+3,8m+4 transmission opportunity corresponding resources are different from the frequency domain positions of the 8m+5,8m+6,8m+7,8m+8 transmission opportunity corresponding resources, wherein the aboveRepresenting a rounding up operation.

7. The method of claim 6 wherein the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are signaled by a higher layer; the fixed deviation is predefined.

8. The method of claim 6, wherein determining the time domain frequency domain locations of the remaining K-1 transmission opportunities based on the time domain frequency domain location of the first of the K transmission opportunities further comprises:

the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are the same, or the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are partially or completely inserted with a fixed deviation, the frequency domain positions of the corresponding resources of the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are the same, or the frequency domain positions of the corresponding resources of the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are partially or completely inserted with a fixed deviation, and the frequency domain positions of the corresponding resources of the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are different from the frequency domain positions of the corresponding resources of the 8 < m+3,8 < m+4,8 >.8 < m+7,8 >Representing a rounding up operation.

9. The method of claim 8, wherein the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+1,8m+2 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+3,8m+4 transmission opportunities are signaled by a higher layer, and the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+5,8m+6 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+7,8m+8 transmission opportunities are signaled by a higher layer; the fixed deviation is predefined.

10. The method of claim 6, wherein when K is greater than or equal to 8, determining the time domain frequency domain locations of the remaining K-1 transmission opportunities from the time domain frequency domain location of the first transmission opportunity of the K transmission opportunities comprises:

the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunities are partially or fully inserted with a fixed deviation, the frequency domain positions of the corresponding resources of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunities are partially or fully inserted with a fixed deviation, and the frequency domain positions of the corresponding resources of the 8 < m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunities are different from the frequency domain positions of the corresponding resources of the 8 < m+5,8 < m+6,8 >Representing a rounding up operation.

11. The method of claim 6, wherein when K is greater than or equal to 4 and less than 8, determining the time domain frequency domain locations of the remaining K-1 transmission opportunities from the time domain frequency domain location of the first of the K transmission opportunities further comprises:

The frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+5,8m+6 transmission opportunities are partially or completely inserted with a fixed offset, the frequency domain positions of the resources corresponding to the 8m+3,8m+4,8m+7,8m+8 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8m+1, 8m+8 transmission opportunities are the sameThe frequency domain position of the corresponding resource of the 2,8m+5,8m+6 transmission opportunities is partially or completely inserted with a fixed offset, and the frequency domain position of the corresponding resource of the 8m+1,8m+2,8m+5,8m+6 transmission opportunities is different from the frequency domain position of the corresponding resource of the 8m+3,8m+4,8m+7,8m+8 transmission opportunities, the method comprises the steps ofRepresenting an upward rounding operation; the fixed deviation is predefined.

12. A method for resource allocation, comprising:

transmitting at least one of the following objects to the terminal: the method comprises the steps of resource allocation information and redundancy version information, so that the terminal determines time domain and frequency domain positions of a plurality of transmission opportunities, wherein the time domain and frequency domain positions of the plurality of transmission opportunities are used periodically, each period has K transmission opportunities of the same transmission block, and K is a positive integer; the value of K is indicated by at least one of the following: first higher layer signaling, first physical layer signaling; the resource allocation information indicates a time domain frequency domain position of a first transmission opportunity; the redundancy version information is indicated by at least one of: a first high layer signaling, a first physical layer signaling, a second high layer signaling, a second physical layer signaling;

The redundancy version information = { a, a, a, a }, wherein the a is taken from the set {0,1,2,3}, the K is greater than or equal to 2, and determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises: the frequency domain positions of all the odd transmission opportunities corresponding to the resources are the same, or the frequency domain positions of part or all of the odd transmission opportunities corresponding to the resources are inserted with a fixed deviation, the frequency domain positions of all the even transmission opportunities corresponding to the resources are the same, or the frequency domain positions of part or all of the even transmission opportunities corresponding to the resources are partially or fully inserted with a fixed deviation, and the frequency domain positions of the odd transmission opportunities corresponding to the resources are different from the frequency domain positions of the even transmission opportunities corresponding to the resources;

the redundancy version information = { a, b, a, b }, where,the a and the b are all taken from a set {0,1,2,3}, and the a and the b have different values, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity in the K transmission opportunities comprises: the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, and the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are different Representing a rounding up operation.

13. The method of claim 12, wherein the step of determining the position of the probe is performed,

the offset size of the frequency domain position of the resource corresponding to the odd transmission opportunity and the frequency domain position corresponding to the even transmission opportunity is notified by a high-layer signaling;

the fixed deviation is predefined.

14. The method of claim 12, wherein offset magnitudes of the frequency domain locations of the resources corresponding to the 4m+1,4m+2 th transmission opportunities and the frequency domain locations of the resources corresponding to the 4m+3,4m+4 th transmission opportunities are signaled by a higher layer; the fixed deviation is predefined.

15. The method of claim 14, wherein determining the time domain frequency domain locations of the remaining K-1 transmission opportunities based on the time domain frequency domain location of the first of the K transmission opportunities further comprises:

the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are the same, or the 4m+1,4m+4 transmission opportunities correspondInserting a fixed deviation into part or all of the frequency domain positions of the resources, wherein the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are the same or the frequency domain positions corresponding to the 4m+2,4m+3 transmission opportunities are partially or all inserted into a fixed deviation, and the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 4m+2,4m+3 transmission opportunities, wherein the frequency domain positions of the resources corresponding to the 4m+1,4m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 4m+2,4m+3 transmission opportunities Representing a rounding up operation.

16. The method of claim 14, wherein the step of providing the first information comprises,

the offset size of the frequency domain position of the 4m+1 transmission opportunity corresponding resource and the frequency domain position of the 4m+2,4m+3 transmission opportunity corresponding resource is notified by the high-level signaling, and the offset size of the frequency domain position of the 4m+2,4m+3 transmission opportunity corresponding resource and the frequency domain position of the 4m+4 transmission opportunity corresponding resource is notified by the high-level signaling; the fixed deviation is predefined.

17. The method of claim 12, wherein the redundancy version information = { a, b, c, d }, the a, b, c, d is taken from a set {0,1,2,3}, and the a, b, c, d values are different, and when the K is greater than or equal to 4, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises:

the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are partially or fully inserted with a fixed offset, the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are partially or fully inserted with a fixed offset, and the frequency domain positions of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities are different from the frequency domain positions of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities, wherein The saidRepresenting a rounding up operation.

18. The method of claim 17, wherein the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+1,8m+2,8m+3,8m+4 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+5,8m+6,8m+7,8m+8 transmission opportunities are signaled by a higher layer; the fixed deviation is predefined.

19. The method of claim 17, wherein determining the time domain frequency domain locations of the remaining K-1 transmission opportunities based on the time domain frequency domain location of the first of the K transmission opportunities further comprises:

the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < 2 >, 8 < m+5,8 < m+6 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2 >, 8 < m+5,8 < m+6 > transmission opportunities are partially or fully inserted with a fixed deviation, the frequency domain positions of the corresponding resources of the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are partially or fully inserted with a fixed deviation, and the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are different from the frequency domain positions of the corresponding resources of the 8 < m+3,8 < m+4,8 > m+7,8 > transmission opportunities, wherein Representing a rounding up operation.

20. The method of claim 19, wherein the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+1,8m+2 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+3,8m+4 transmission opportunities are signaled by a higher layer, and the offset magnitudes of the frequency domain locations of the resources corresponding to the 8m+5,8m+6 transmission opportunities and the frequency domain locations of the resources corresponding to the 8m+7,8m+8 transmission opportunities are signaled by a higher layer; the fixed deviation is predefined.

21. The method of claim 17, wherein when K is greater than or equal to 8, determining the time domain frequency domain locations of the remaining K-1 transmission opportunities from the time domain frequency domain location of the first transmission opportunity of the K transmission opportunities comprises:

the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < 2 >, 8 < m+3,8 < m+4 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2 >, 8 < m+3,8 < m+4 > transmission opportunities are partially or fully inserted with a fixed deviation, the frequency domain positions of the corresponding resources of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunities are the same or the frequency domain positions of the corresponding resources of the 8 < th > m+5,8 < m+6,8 < m+7,8 < m+8 > transmission opportunities are partially or fully inserted with a fixed deviation, and the frequency domain positions of the corresponding resources of the 8 < th > m+1,8 < m+2,8 < m+3,8 < m+4 > transmission opportunities are different from the frequency domain positions of the corresponding resources of the 8 < th > m+5,8 < m+6,8 > m+7,8 < m+8 > transmission opportunities, wherein Representing a rounding up operation.

22. The method of claim 17, wherein when K is greater than or equal to 4 and less than 8, determining the time domain frequency domain locations of the remaining K-1 transmission opportunities from the time domain frequency domain location of the first of the K transmission opportunities further comprises:

the frequency domain positions of the resources corresponding to the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8 < th > m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are partially or completely inserted with a fixed deviation, the frequency domain positions of the resources corresponding to the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 8 < th > m+3,8 < m+4,8 < m+7,8 < m+8 > transmission opportunities are partially or completely inserted with a fixed deviation, and the frequency domain positions of the resources corresponding to the 8 < m+1,8 < m+2,8 < m+5,8 < m+6 > transmission opportunities are different from the frequency domain positions of the resources corresponding to the 8 < m+3,8 < m+4,8 > m+7,8 < m+8Representing a rounding up operation.

23. A resource allocation apparatus, applied to a terminal, comprising:

a determining module for determining time domain frequency domain positions of a plurality of transmission opportunities according to at least one of the following objects: the method comprises the steps of resource allocation information and redundancy version information, wherein time domain and frequency domain positions of a plurality of transmission opportunities are used periodically, each period has K transmission opportunities of the same transmission block, and K is a positive integer; the value of K is indicated by at least one of the following: first higher layer signaling, first physical layer signaling; the resource allocation information indicates a time domain frequency domain position of a first transmission opportunity; the redundancy version information is indicated by at least one of: a first high layer signaling, a first physical layer signaling, a second high layer signaling, a second physical layer signaling;

the redundancy version information = { a, b, a, b }, wherein the a and b are all taken from the set {0,1,2,3}, and the a and b are different in value, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises: the frequency domain positions of the resources corresponding to the 4m+1,4m+2 transmission opportunities are the same, or the frequency domain positions of the resources corresponding to the 4m+1,4m+2 transmission opportunities are partially or completely inserted into one The frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are the same or the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are partially or wholly inserted with a fixed deviation, and the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources, wherein the method comprises the steps ofRepresenting a rounding up operation.

24. A resource allocation apparatus, for use in a base station, comprising:

a transmitting module, configured to transmit at least one of the following objects to a terminal: the method comprises the steps of resource allocation information and redundancy version information, so that the terminal determines time domain and frequency domain positions of a plurality of transmission opportunities, wherein the time domain and frequency domain positions of the plurality of transmission opportunities are used periodically, each period has K transmission opportunities of the same transmission block, and K is a positive integer; the value of K is indicated by at least one of the following: first higher layer signaling, first physical layer signaling; the resource allocation information indicates a time domain frequency domain position of a first transmission opportunity; the redundancy version information is indicated by at least one of: a first high layer signaling, a first physical layer signaling, a second high layer signaling, a second physical layer signaling;

the redundancy version information = { a, b, a, b }, wherein the a and b are all taken from the set {0,1,2,3}, and the a and b are different in value, and when the K is greater than or equal to 2, determining the time domain frequency domain positions of the remaining K-1 transmission opportunities according to the time domain frequency domain position of the first transmission opportunity of the K transmission opportunities comprises: the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are the same, or the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are partially or fully inserted with a fixed deviation, and the frequency domain positions of the 4m+1,4m+2 transmission opportunity corresponding resources are different from the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources, wherein the frequency domain positions of the 4m+3,4m+4 transmission opportunity corresponding resources are different Representing a rounding up operation.

25. A storage medium comprising a stored program, wherein the program when run performs the method of any one of claims 1 to 11, or claims 12 to 22.

26. A processor for running a program, wherein the program when run performs the method of any one of claims 1 to 11, or claims 12 to 22.