CN110048819A - A kind of information sending and receiving method, the network equipment, user equipment - Google Patents

Abstract

The invention discloses an information sending and receiving method, network equipment, user equipment, communication equipment and storage medium, wherein the method comprises: sending control information in a control resource in a set of remaining system information RMSI control resources, the The control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located; wherein, the number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, so as to achieve a coverage close to the synchronization channel. Effect.

Description

A kind of information sending and receiving method, network equipment, user equipment

technical field

The present invention relates to information processing technology in the field of communication, and in particular, to a method for sending and receiving information, network equipment, user equipment, communication equipment and storage medium.

Background technique

In the current 5G standardization, the synchronization block (SS block) contains synchronization signals and system broadcast information. When the terminal is used for initial cell selection, the default period is 20ms, and the synchronization period of the terminal after accessing the system can be configured as 5ms, 10ms or 20ms. Unlike LTE, the 5G standard defines a variety of subcarrier spacings due to the increased range of application bandwidths. For synchronization channels and broadcast channels (such as shown in Figure 1), the sub-carrier spacing of 15 kHz and 30 kHz is used below 6 GHz, and the sub-carrier spacing of 120 kHz and 240 kHz is used above 6 GHz. On the other hand, due to the increase of the carrier frequency, the path loss and fading increase, in order to ensure a certain coverage of the cell, the concept of beamforming is introduced in the 5G standard. However, the signal width after beamforming is limited and cannot cover omnidirectionally.

SUMMARY OF THE INVENTION

The main purpose of the present invention is to provide an information sending and receiving method, network equipment, user equipment, communication equipment and storage medium, aiming at solving the above problems existing in the prior art.

In order to achieve the above object, the present invention provides a method for sending information, which is applied to a network device, and the method includes:

Sending control information in a control resource in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides an information receiving method, which is applied to terminal equipment, and the method includes:

receiving control information sent by the network side in the control resources in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides a network device, comprising:

a transmission unit, configured to send control information in the control resource in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides a network device, comprising:

a first communication interface, configured to send control information in a control resource in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides a terminal device, characterized in that it includes:

a receiving unit, configured to receive the control information sent by the network side in the control resources in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides a terminal device, including:

a second communication interface, configured to receive control information sent by the network side in the control resources in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, that is, each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The present invention provides a communication device comprising: a processor and a memory for storing a computer program executable on the processor,

Wherein, the processor is configured to execute the steps of the method when running the computer program.

The present invention provides a storage medium on which a computer program is stored, wherein the computer program implements the steps of the aforementioned method when executed by a processor.

An information sending and receiving method, network equipment, user equipment, communication equipment and storage medium proposed by the present invention correspond to the number of beams corresponding to the RMSI control resource set and the number of beams corresponding to the synchronization block, and through the RMSI The control information is sent in the control resources in the control resource set to indicate the time-frequency resources where the remaining system information is located; thus, a multi-beam scanning method is used to transmit the remaining system information. To improve the coverage performance within the system.

Description of drawings

1 is a schematic diagram of the design of a synchronization channel and a broadcast channel according to an embodiment of the present invention;

2 is a schematic flowchart of a method for sending information according to an embodiment of the present invention;

3 is a schematic diagram 1 of a multi-beam time-frequency pattern design of an RMSI control resource set according to an embodiment of the present invention;

4 is a schematic diagram 2 of a multi-beam time-frequency pattern design of an RMSI control resource set according to an embodiment of the present invention;

5 is a schematic diagram 3 of a multi-beam time-frequency pattern design of an RMSI control resource set according to an embodiment of the present invention;

FIG. 6 is a schematic diagram 1 of the composition structure of a network device according to an embodiment of the present invention;

FIG. 7 is a schematic diagram 2 of a composition structure of a network device according to an embodiment of the present invention.

Detailed ways

The present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments.

Embodiment 1.

An embodiment of the present invention provides an information sending method, which is applied to a network device, including: sending control information in a control resource in an RMSI control resource set, where the control information is at least used to indicate the time-frequency resource where the remaining system information RMSI is located s position;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block.

The sending of the control information within the control resources in the RMSI control resource set may be sending the RMSI within a sending period of the remaining system information RMSI.

Correspondingly, the number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block, which may be the number of beams corresponding to the RMSI control resource set included in the transmission cycle of the one RMSI control resource set, and The number of beams corresponding to the synchronization blocks in one synchronization period is the same. It is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

Specifically, as shown in Figure 2, it includes:

Step 201: The number of beams corresponding to the RMSI control resource set in the RMSI transmission period is the same as the number of beams corresponding to the synchronization block in the synchronization block transmission period; wherein, the transmission period of the RMSI is the positive value of the transmission period of the synchronization block. Integer multiple; each RMSI control resource set is associated with a synchronization block, and the two are at least spatially quasi-co-located QCLed; the number of ports in each RMSI control resource set and the number of ports in the one synchronization block are The same; and the ports in each RMSI control resource set are sequentially associated with the ports in the one synchronization block according to the characteristic rules;

Step 202: Send control information in the control resources in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located.

The solution provided by this embodiment can support the terminal to continue to read the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel, and also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI control resource set multi-beam design, its basic ideas mainly include:

Through the control information sent in the control resources in the RMSI control resource set, the control information indicates the time-frequency position where the remaining system information is located;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, which depends on the synchronization The beam direction of the block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the transmission period of the RMSI is a positive integer multiple of the synchronization block transmission period.

For example, the number of beams corresponding to the RMSI control resource set in one cycle may be the same as the number of beams corresponding to the synchronization block in one cycle, specifically including:

The period of the RMSI control resource set is an integer multiple of the sync block period; for example, if the sync block period is 5ms, then the RMSI control resource set period is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period It is an integer multiple of 10ms.

In addition, each RMSI control resource set is associated with a sync block, and both are at least spatially quasi-co-located QCLed.

The RMSI control resource set multi-beam time-frequency pattern design, including:

Design 1, the number of ports in each RMSI control resource set is the same as the number of ports in the one synchronization block; and the ports in the control resources in each RMSI control resource set are the same as the ports in one synchronization block are related in sequence according to the characteristic rules. In an RMSI transmission period, the RMSI control resource set and the associated synchronization block are respectively transmitted in the same time slot.

The two sets of RMSI control resources are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

Specifically, in a transmission cycle of an RMSI control resource set, the RMSI control resource set is respectively set in the first two symbols in the first time slot containing two synchronization blocks;

The beam corresponding to the RMSI control resource set corresponds to the beam of the synchronization block in the first time slot.

The time slot (that is, the time slot containing the RMSI control resource set) contains two synchronization blocks, and the first two symbols of the time slot respectively have an RMSI control resource set, and the beam of each RMSI control resource set is related to the beam in the time slot. Beam correspondence of a sync block;

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively sequentially associated with the beams corresponding to the two synchronization blocks in the time slot.

That is to say, in one RMSI transmission period, two RMSI control resource sets are set in one time slot including two synchronization blocks;

The beams of the two RMSI control resource sets are respectively associated with the beams corresponding to the two synchronization blocks in the time slot.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The RMSI control resource set and the associated synchronization block are respectively sent in different time slots.

The RMSI control resource set is located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

Specifically, in one RMSI transmission cycle, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used to demodulate the control channel and data channel, and finally obtain the remaining system information; this solution implements a multi-beam scanning method, which can effectively achieve omnidirectional coverage in a cell to improve the coverage performance of the system.

Embodiment two,

An embodiment of the present invention provides an information sending method, which is applied to a terminal device, including: control information sent in an RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block.

Specifically, it may be to receive an RMSI control resource set within one RMSI sending cycle; the RMSI control resource set is at least used to indicate the remaining system information RMSI;

Wherein, the number of RMSI control resource sets included in the transmission period of the one RMSI control resource set is the same as the number of beams of the synchronization block in one synchronization period.

Specifically, the sending period of the RMSI is a positive integer multiple of the synchronization period.

The solution provided by this embodiment can support the terminal to continue to read the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel. It also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI control resource set multi-beam design, its basic ideas mainly include:

Through the control information sent in the control resources in the RMSI control resource set, the control information indicates the time-frequency position where the remaining system information is located;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, which depends on the synchronization The beam direction of the block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the number of beams corresponding to the RMSI control resource set in one cycle is the same as the number of beams in the synchronization block in one cycle, specifically including:

The period of the RMSI control resource set is an integer multiple of the sync block period; for example, if the sync block period is 5ms, then the RMSI control resource set period is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period It is an integer multiple of 10ms.

In addition, each RMSI control resource set is associated with a sync block, and both are at least spatially quasi-co-located QCLed.

RMSI control resource set multi-beam time-frequency pattern design, the number of ports in each RMSI control resource set is the same as the number of ports in the one synchronization block; and the control resources in each RMSI control resource set The ports in a synchronous block are sequentially associated with the ports in a synchronization block according to the characteristic rules.

Specifically include:

design one,

The port number of each RMSI control resource set is the same as the port number of the one synchronization block; and the port in the control resource in each RMSI control resource set and the port in one synchronization block are according to the characteristics. The rules are sequentially associated. In an RMSI transmission period, the RMSI control resource set and the associated synchronization block are respectively transmitted in the same time slot.

The two sets of RMSI control resources are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

Specifically, a time slot containing two RMSI control resource sets includes two synchronization blocks, the first two symbols of the time slot respectively have an RMSI control resource set, and the beam domain of each RMSI control resource set is the same as that in the time slot. Beam correspondence of a sync block;

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively sequentially associated with the beams corresponding to the two synchronization blocks in the time slot.

That is, in one RMSI transmission cycle, two RMSI control resource sets are set in one time slot including two synchronization blocks.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The RMSI control resource set and the associated synchronization block are sent in different time slots, respectively.

The RMSI control resource set is located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

Specifically, in one RMSI transmission period, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used for the demodulation of the control channel and the data channel, and finally the remaining system information is obtained; this scheme realizes the transmission of the remaining system information in the multi-beam scanning mode, which can effectively realize the omnidirectional coverage in the cell, so as to improve the System coverage performance.

Embodiment three,

An embodiment of the present invention provides a network device, as shown in FIG. 6 , including:

a transmission unit 61, configured to send control information in the control resources in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block.

Specifically, in one RMSI sending period, the control information is sent in the RMSI control resource set; the control information is at least used to indicate the remaining system information RMSI;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. It is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

Wherein, the transmission period of the RMSI is a positive integer multiple of the synchronous transmission period;

The solution provided by this embodiment can support the terminal to continue to read the control information in the control resources in the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel. It also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI controls the multi-beam design of the resource set, and the network device may further include: a processing unit 52, configured to control the control information sent in the RMSI control resource set, where the control information indicates the time-frequency position where the remaining system information is located;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, depending on the The beam direction of the synchronization block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the number of beams corresponding to the RMSI control resource set in one cycle may be the same as the number of beams corresponding to the synchronization block in one cycle, specifically including:

The period of the RMSI control resource set is an integer multiple of the sync block period; for example, if the sync block period is 5ms, then the RMSI control resource set period is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period It is an integer multiple of 10ms.

The RMSI control resource set multi-beam time-frequency pattern design, including:

Design 1, the processing unit 62 controls the number of ports in each RMSI control resource set to be the same as the number of ports in the one synchronization block; and the corresponding ports in the control resources in each RMSI control resource set The ports in a synchronization block are sequentially associated according to the characteristic rules.

and the two RMSI control resource sets are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

The time slot (that is, the time slot containing the RMSI control resource set) contains two synchronization blocks, and the first two symbols of the time slot respectively have an RMSI control resource set, and the beam of each RMSI control resource set is related to the beam in the time slot. Beam correspondence of a sync block;

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively sequentially associated with the beams corresponding to the two synchronization blocks in the time slot.

In one RMSI transmission period, two RMSI control resource sets are set in one time slot including two sync blocks.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 OFDM symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The processing unit 62 is configured to control the RMSI control resource set and the associated synchronization block to be sent in different time slots respectively. and controlling the RMSI control resource set to be located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

In one RMSI transmission cycle, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used for the demodulation of the control channel and the data channel, and finally the remaining system information is obtained; this scheme adopts the multi-beam scanning method to transmit the remaining system information, which can effectively realize the omnidirectional coverage in the cell, so as to improve the System coverage performance.

Embodiment four,

An embodiment of the present invention provides a network device, as shown in FIG. 7 , including:

a first communication interface 71, configured to send control information in a control resource in the RMSI control resource set, where the control information is at least used to indicate the position of the time-frequency resource where the remaining system information RMSI is located;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block. Each RMSI control resource set is associated with a sync block, and both are at least spatially quasi-co-located QCLed.

Wherein, the transmission period of the RMSI control resource set is an integer multiple of the synchronization block transmission period.

The solution provided by this embodiment can support the terminal to continue to read the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel. It also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI control resource set multi-beam design, the network device may further include: a processing unit 52, configured to use the control information sent in the control resources in the RMSI control resource set, where the control information indicates the time-frequency where the remaining system information is located Location;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, which depends on the synchronization The beam direction of the block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the number of beams of the RMSI control resource set in one cycle is the same as the number of beams of the synchronization block in one cycle, and it is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least one. The space is intended to be co-located QCLed.

Specifically:

The RMSI transmission period is an integer multiple of the sync block transmission period; for example, if the sync block period is 5ms, the RMSI control resource set period is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period is Integer multiples of 10ms.

The network device also includes:

The first processor 72 is configured to control the number of ports in each RMSI control resource set to be the same as the number of ports in the one synchronization block; and the ports in each RMSI control resource set are the same as one synchronization block The ports in are associated in sequence according to the characteristic rules.

The RMSI control resource set multi-beam time-frequency pattern design, including:

Design 1, the first processor 72 is used to control the number of ports in each RMSI control resource set is the same as the number of ports in the one synchronization block; and the corresponding control resources in the control resources in each RMSI control resource set are the same; Ports are sequentially associated with ports in a synchronization block according to the characteristic rules. In an RMSI transmission cycle, the RMSI control resource set and the associated synchronization block are respectively transmitted in the same time slot;

The two sets of RMSI control resources are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

A time slot containing two RMSI control resource sets contains two synchronization blocks, the first two symbols of the time slot have an RMSI control resource set respectively, and the beam domain of each RMSI control resource set is related to a synchronization block in the time slot. The beam corresponds to;

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively sequentially associated with the beams corresponding to the two synchronization blocks in the time slot.

That is, in one RMSI transmission cycle, two RMSI control resource sets are set in one time slot including two synchronization blocks.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The first processor 72 controls the RMSI control resource set and the associated synchronization block to be sent in different time slots respectively. The RMSI control resource set is controlled to be located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

In one RMSI transmission cycle, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used for the demodulation of the control channel and the data channel, and finally obtain the remaining system information; this scheme realizes the use of multi-beam scanning mode to transmit the remaining system information, which can effectively achieve omnidirectional coverage in the cell, To improve the coverage performance of the system.

Embodiment five,

An embodiment of the present invention provides a terminal device, comprising: a receiving unit configured to receive control information sent by a network side in a control resource in an RMSI control resource set, where the control information is at least used to indicate where the remaining system information RMSI is located. the location of time-frequency resources;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block.

Specifically, it may be to receive an RMSI control resource set within one RMSI sending cycle; the RMSI control resource set is at least used to indicate the remaining system information RMSI;

Wherein, the number of RMSI control resource sets included in the transmission period of the one RMSI control resource set is the same as the number of beams of the synchronization block in one synchronization period.

The solution provided by this embodiment can support the terminal to continue to read the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel. It also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI control resource set multi-beam design, its basic ideas mainly include:

Through the control information sent in the RMSI control resource set, the control information indicates the time-frequency position where the remaining system information is located;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, which depends on the synchronization The beam direction of the block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the number of beams of the RMSI control resource set in one cycle is the same as the number of beams of the synchronization block in one cycle, and it is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least is the spatially quasi-co-located QCLed.

Specifically:

The period of the RMSI control resource set is an integer multiple of the sync block period; for example, if the sync block period is 5ms, then the RMSI control resource set period is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period It is an integer multiple of 10ms.

The RMSI control resource set multi-beam time-frequency pattern design, including:

design one,

The port number of each RMSI control resource set is the same as the port number of the one synchronization block; and the ports in each RMSI control resource set and the ports in a synchronization block are sequentially associated according to the characteristic rule . In an RMSI transmission period, the RMSI control resource set and the associated synchronization block are respectively transmitted in the same time slot.

The two sets of RMSI control resources are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

The receiving unit is configured to receive control information in two RMSI control resource sets in one time slot, the time slot includes two synchronization blocks, and the first two symbols of the time slot respectively have one RMSI control resource set, each The beam domain of the RMSI control resource set corresponds to the beam of one synchronization block in the time slot.

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively sequentially associated with the beams corresponding to the two synchronization blocks in the time slot.

That is, in one RMSI transmission cycle, two RMSI control resource sets are set in one time slot including two synchronization blocks.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The RMSI control resource set and the associated synchronization block are sent in different time slots, respectively.

The RMSI control resource set is located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

In one RMSI transmission cycle, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used for the demodulation of the control channel and the data channel, and finally the remaining system information is obtained; this scheme realizes the multi-beam scanning method, transmits the remaining system information, and can effectively achieve omnidirectional coverage in the cell, with Improve the coverage performance of the system.

Embodiment six,

An embodiment of the present invention provides a terminal device, comprising: a second communication interface for receiving an RMSI control resource set within a sending period of an RMSI control resource set; the RMSI control resource set is at least used to indicate remaining system information RMSI;

The number of beams corresponding to the RMSI control resource set is the same as the number of beams corresponding to the synchronization block.

Specifically, it may be to receive an RMSI control resource set within one RMSI sending cycle; the RMSI control resource set is at least used to indicate the remaining system information RMSI;

Wherein, the number of RMSI control resource sets included in the transmission period of the one RMSI control resource set is the same as the number of beams of the synchronization block in one synchronization period. It is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least spatially quasi-co-located QCLed.

The solution provided by this embodiment can support the terminal to continue to read the RMSI control resource set to obtain the time-frequency position of the remaining system information after completing the synchronization and reading the broadcast information, and then obtain the remaining system information RMSI. The RMSI control resource set is similar to the synchronization channel and the broadcast channel. It also needs to achieve omnidirectional coverage in the cell by beam scanning. Therefore, it involves how the terminal identifies the beam direction of the RMSI control resource set and receives it correctly.

The RMSI control resource set multi-beam design, its basic ideas mainly include:

Through the control information sent in the RMSI control resource set, the control information indicates the time-frequency position where the remaining system information is located;

Alternatively, the RMSI is carried through the RMSI control resource set; that is, the control resource set occupied by the RMSI directly carries the remaining system information.

It should also be pointed out that the control information is sent in at least one RMSI control resource set corresponding to one beam within one RMSI transmission period; wherein, the spatial indication direction of each beam in the at least one beam may be the same or different, which depends on the synchronization The beam direction of the block; and the RMSI included in the time-frequency resources indicated by each beam is the same. That is to say, there are RMSI control resource sets of multiple beams in one cycle, and the spatial direction of each beam depends on the normal direction of the associated synchronization block, but the time-frequency resources indicated by the RMSI control resource set corresponding to each beam include The rest of the system information is the same.

Further, the number of beams of the RMSI control resource set in one cycle is the same as the number of beams of the synchronization block in one cycle, and it is characterized in that each RMSI control resource set is associated with one synchronization block, and the two are at least is the spatially quasi-co-located QCLed.

The period of the RMSI control resource set is an integer multiple of the synchronization block period; specifically, it includes:

For example, if the sync block period is 5ms, the period of the RMSI control resource set is an integer multiple of 5ms; if the sync block period is 10ms, the RMSI control resource set period is an integer multiple of 10ms.

RMSI control resource set multi-beam time-frequency pattern design, the number of ports in each RMSI control resource set is the same as the number of ports in the one synchronization block; and the ports in each RMSI control resource set are the same as one The ports in the synchronization block are sequentially associated according to the characteristic rules, including:

Design 1.

The port number of each RMSI control resource set is the same as the port number of the one synchronization block; and the ports in each RMSI control resource set and the ports in a synchronization block are sequentially associated according to the characteristic rule . In an RMSI transmission period, the RMSI control resource set and the associated synchronization block are respectively transmitted in the same time slot.

The two sets of RMSI control resources are respectively located in the first two OFDM symbols in a time slot containing two synchronization blocks;

The RMSI control resource sets occupy one OFDM symbol respectively, and the beams corresponding to the two RMSI control resource sets and the beams corresponding to the two synchronization blocks in the time slot are sequentially associated.

Specifically, the time slot in which two RMSI control resource sets are sent includes two synchronization blocks, the first two symbols of the time slot respectively have an RMSI control resource set, and the beam domain of each RMSI control resource set is the same as that in the time slot. Beam correspondence of a sync block;

As shown in Figure 3: The RMSI control resource set with the same beam direction and an associated synchronization block are sent in the same time slot, and the RMSI control resource set is located on the first two symbols of the time slot. Each beam direction The corresponding RMSI control resource set occupies one OFDM symbol. The same design can be used for different subcarrier spacing and traffic scenarios.

Design two,

The RMSI control resource set at least includes: a first RMSI control resource set and a second RMSI control resource set;

Wherein, the first RMSI control resource set is located in the previous one or two OFDM symbols in a time slot including two synchronization blocks; the second RMSI control resource set is located in the middle one or two OFDM symbols in the time slot;

The beams corresponding to the first RMSI control resource set and the second RMSI control resource set are respectively associated with the beams of the two synchronization blocks in the time slot in sequence. That is, in one RMSI transmission cycle, two RMSI control resource sets are set in one time slot including two synchronization blocks.

The time slot contains two synchronization blocks, and one or two OFDM symbols before the time slot have a first RMSI control resource set, which corresponds to a beam of a synchronization block; one or two OFDM symbols in the middle have a second RMSI control resource set and correspond to a beam of a sync block.

As shown in Figure 4, the RMSI control resource set and synchronization block with the same beam direction are sent in the same time slot, and the RMSI control resource set corresponding to each beam direction occupies 2 symbols. There are different designs for different subcarrier spacing and service scenarios.

Design three:

The RMSI control resource set and the associated synchronization block are respectively sent in different time slots.

The RMSI control resource set is located on at least one OFDM symbol; and the time slot for transmitting the RMSI control resource set includes consecutive n RMSI control resource sets, where n is a positive integer.

In one RMSI transmission cycle, the RMSI control resource set and the synchronization block with the same beam direction are respectively transmitted in different time slots. That is, the time slot does not include a synchronization block, and in the time slot including the RMSI control resource set, the RMSI control resource set is set on at least one OFDM symbol; and the time slot for sending the RMSI control resource set includes consecutive n A set of RMSI control resources, n is a positive integer. Specifically, each RMSI control resource set occupies one OFDM symbol or two OFDM symbols.

In this design, there are M time slots in a remaining system information broadcast period, M is a positive integer; there are sum(n _i ) RMSI control resource sets in total, where n _i represents the number of RMSI control resource sets in the i-th time slot number, i=1,...M;;

M time slots are consecutive in time, or non-consecutive;

The period and time slot offset for sending the RMSI control resource set are pre-configured to be fixed, or can be configured through system information or high-layer signaling. In addition, the user can know the transmission period and time slot offset of the RMSI control resource set corresponding to a secondary synchronization channel through system configuration or high-level signaling.

As shown in Figure 5: RMSI control resource sets and synchronization blocks with the same beam direction are sent in different time slots, and can have the same design for different subcarrier intervals and service scenarios.

It can be seen that by adopting this solution, the beam corresponding to the RMSI control resource set can be associated with the beam corresponding to the synchronization block. Since the beam corresponds to the spatial channel, the spatial channel also has a certain degree of correlation, so the terminal side can obtain the channel information based on the synchronization block. , the obtained channel information can be further used for the demodulation of the control channel and the data channel, and finally obtain the remaining system information; this scheme realizes the use of multi-beam scanning mode to transmit the remaining system information, which can effectively achieve omnidirectional coverage in the cell, To improve the coverage performance of the system.

Further, the present application also provides a communication device, comprising: a processor and a memory for storing a computer program that can be run on the processor,

Wherein, when the processor is configured to run the computer program, the steps of the method of one embodiment are executed. And the processor can execute each step of the method provided in any one of Embodiments 1 to 2, which will not be repeated here.

The present application further provides a storage medium on which a computer program is stored, wherein, when the computer program is executed by a processor, the steps of any one of the methods described in Embodiments 1 to 2 are implemented.

It should be noted that, herein, the terms "comprising", "comprising" or any other variation thereof are intended to encompass non-exclusive inclusion, such that a process, method, article or device comprising a series of elements includes not only those elements, It also includes other elements not expressly listed or inherent to such a process, method, article or apparatus. Without further limitation, an element qualified by the phrase "comprising a..." does not preclude the presence of additional identical elements in a process, method, article or apparatus that includes the element.

The above-mentioned serial numbers of the embodiments of the present invention are only for description, and do not represent the advantages or disadvantages of the embodiments.

From the description of the above embodiments, those skilled in the art can clearly understand that the method of the above embodiment can be implemented by means of software plus a necessary general hardware platform, and of course can also be implemented by hardware, but in many cases the former is better implementation. Based on this understanding, the technical solutions of the present invention can be embodied in the form of software products in essence or the parts that make contributions to the prior art, and the computer software products are stored in a storage medium (such as ROM/RAM, magnetic disk, CD-ROM), including several instructions to make a terminal device (which may be a mobile phone, a computer, an apparatus, an air conditioner, or a network device, etc.) execute the methods described in the various embodiments of the present invention.

The above are only preferred embodiments of the present invention, and are not intended to limit the scope of the present invention. Any equivalent structure or equivalent process transformation made by using the contents of the description and drawings of the present invention, or directly or indirectly applied in other related technical fields , are similarly included in the scope of patent protection of the present invention.

Claims (40)

1. a kind of method for sending information is applied to the network equipment, which is characterized in that the described method includes:

Control information is sent in the control resource in remaining system information RMSI control resource collection, the control information is at least It is used to indicate the position of the running time-frequency resource where remaining system information RMSI；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

2. the method according to claim 1, wherein the sending cycle of the RMSI is that the synchronization blocks send week The positive integer times of phase.

3. the method according to claim 1, wherein the RMSI corresponding wave beam number of control resource collection with The corresponding wave beam number of synchronization blocks is identical, are as follows:

Each RMSI control resource collection is associated with a synchronization blocks, and the two is at least space and intends co-located QCLed.

4. according to the method described in claim 3, it is characterized in that, port number and the institute of each RMSI control resource collection It is identical for stating the port number in a synchronization blocks；And port in each RMSI control resource collection and one same The port walked in block is successively associated according to characterization rules.

5. according to the method described in claim 3, it is characterized in that, the RMSI is controlled in the sending cycle of a RMSI Resource collection is sent in identical time slot respectively with associated synchronization blocks.

6. according to the method described in claim 5, it is characterized in that, it includes two that two RMSI control resource collections, which are located at, In the first two OFDM symbol in one time slot of a synchronization blocks；

Wherein, the RMSI control resource collection occupies an OFDM symbol respectively, and two RMSI control resource collections are corresponding Wave beam, successively associated with the wave beam of two synchronization blocks in the time slot.

7. according to the method described in claim 5, it is characterized in that, RMSI control resource collection includes at least: first RMSI controls resource collection and the 2nd RMSI controls resource collection；

Wherein, the first RMSI controls resource collection and is located at comprising there are two previous or the first two in synchronization blocks a time slot OFDM symbol；2nd RMSI control resource collection is located at one or two OFDM symbol of the centre in the time slot；

Wherein, the first RMSI control resource collection and the corresponding wave beam of the 2nd RMSI control resource collection, respectively with institute Stating two in time slot corresponding wave beams of synchronization blocks is successively associated.

8. according to the method described in claim 3, it is characterized in that, the RMSI controls resource collection and associated synchronization blocks It is sent in different time slots respectively.

9. according to the method described in claim 8, it is characterized in that, RMSI control resource collection is located at least one OFDM On symbol；And resource collection, n are controlled comprising continuous n RMSI in the time slot for sending RMSI control resource collection For positive integer.

10. a kind of message receiving method is applied to terminal device, which is characterized in that the described method includes:

The control information that network side is sent in the control resource in RMSI control resource collection is received, the control information is at least It is used to indicate the position of the running time-frequency resource where remaining system information RMSI；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

11. according to the method described in claim 10, it is characterized in that, the sending cycle of the RMSI is synchronization blocks transmission The positive integer times in period.

12. according to the method described in claim 10, it is characterized in that, the corresponding wave beam number of RMSI control resource collection Wave beam number corresponding with synchronization blocks is identical, are as follows:

Each RMSI control resource collection is associated with a synchronization blocks, and the two is at least space and intends co-located QCLed.

13. according to the method for claim 12, which is characterized in that the port number of each RMSI control resource collection with Port number in one synchronization blocks is identical；And the port in each RMSI control resource collection with it is one Port in synchronization blocks is successively associated according to characterization rules.

14. according to the method for claim 12, which is characterized in that RMSI control resource collection with it is associated synchronous Block is sent in identical time slot respectively.

15. according to the method for claim 14, which is characterized in that two RMSI control resource collections are located at and include In the first two OFDM symbol in one time slot of two synchronization blocks；

Wherein, the RMSI control resource collection occupies an OFDM symbol respectively, and two RMSI control resource collections are corresponding Wave beam, wave beam corresponding with two synchronization blocks in the time slot is successively associated.

16. according to the method for claim 14, which is characterized in that the RMSI control resource collection includes at least: first RMSI controls resource collection and the 2nd RMSI controls resource collection；

Wherein, the first RMSI controls resource collection and is located at comprising there are two previous or the first two in synchronization blocks a time slot OFDM symbol；2nd RMSI control resource collection is located at one or two OFDM symbol of the centre in the time slot；

Wherein, the first RMSI control resource collection and the corresponding wave beam of the 2nd RMSI control resource collection, respectively with institute Stating two in time slot corresponding wave beams of synchronization blocks is successively associated.

17. according to the method for claim 12, which is characterized in that the RMSI controls resource set and associated synchronization blocks It is sent in different time slots respectively.

18. according to the method for claim 17, which is characterized in that the RMSI control resource collection is located at least one In OFDM symbol；And resource set is controlled comprising continuous n RMSI in the time slot for sending RMSI control resource collection It closes, n is positive integer.

19. a kind of network equipment, comprising:

Transmission unit, for sending control information in the control resource in RMSI control resource collection, the control information is extremely It is used to indicate the position of the running time-frequency resource where remaining system information RMSI less；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

20. a kind of network equipment, comprising:

First communication interface, for sending control information, the control letter in the control resource in RMSI control resource collection Breath is at least used to indicate the position of the running time-frequency resource where remaining system information RMSI；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

21. the network equipment according to claim 20, which is characterized in that the sending cycle of the RMSI is the synchronization blocks The positive integer times of sending cycle.

22. the network equipment according to claim 20, which is characterized in that the RMSI controls the corresponding wave beam of resource collection Number wave beam number corresponding with synchronization blocks is mutually all that each RMSI control resource collection is associated with a synchronization blocks, and two Person is at least space and intends co-located QCLed.

23. the network equipment according to claim 22, which is characterized in that the network equipment further include:

First processor, the end in port number and one synchronization blocks for controlling each RMSI control resource collection Mouth number is identical；And the port in each RMSI control resource collection and the port in one synchronization blocks be according to Characterization rules are successively associated.

24. the network equipment according to claim 23, which is characterized in that the network equipment further include:

First processor, for controlling in the sending cycle of a RMSI, RMSI control resource collection with it is associated Synchronization blocks are sent in identical time slot respectively.

25. the network equipment according to claim 24, which is characterized in that first processor, for controlling two RMSI controls Resource collection processed is located at comprising there are two in the first two OFDM symbol in synchronization blocks a time slot；

Wherein, the RMSI control resource collection occupies an OFDM symbol respectively, and two RMSI control resource collections are corresponding Wave beam, wave beam corresponding with two synchronization blocks in the time slot is successively associated.

26. according to the method for claim 24, which is characterized in that the RMSI control resource collection includes at least: first RMSI controls resource collection and the 2nd RMSI controls resource collection；

Wherein, the first RMSI controls resource collection and is located at comprising there are two previous or the first two in synchronization blocks a time slot OFDM symbol；2nd RMSI control resource collection is located at one or two OFDM symbol of centre in the time slot；

Wherein, the first RMSI control resource collection and the corresponding wave beam of the 2nd RMSI control resource collection, respectively with institute Stating two in time slot corresponding wave beams of synchronization blocks is successively associated.

27. the network equipment according to claim 22, which is characterized in that first processor, for controlling the RMSI control Resource set processed is sent in different time slots respectively from associated synchronization blocks.

28. the network equipment according to claim 27, which is characterized in that first processor, for controlling the RMSI control Resource collection processed is located at least one OFDM symbol；And comprising connecting in the time slot for sending RMSI control resource collection N continuous RMSI controls resource collection, and n is positive integer.

29. a kind of terminal device, which is characterized in that the terminal device includes:

Receiving unit, the control information sent in the control resource in RMSI control resource collection for receiving network side, institute State the position that control information is at least used to indicate the running time-frequency resource where remaining system information RMSI；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

30. a kind of terminal device, which is characterized in that the terminal device includes:

Second communication interface, the control letter sent in the control resource in RMSI control resource collection for receiving network side Breath, the control information are at least used to indicate the position of the running time-frequency resource where remaining system information RMSI；

Wherein, the corresponding wave beam number of RMSI control resource collection wave beam number corresponding with synchronization blocks is identical.

31. terminal device according to claim 30, which is characterized in that the sending cycle of the RMSI is the synchronization blocks The positive integer times of sending cycle.

32. terminal device according to claim 30, which is characterized in that the RMSI controls the corresponding wave beam of resource collection Number wave beam number corresponding with synchronization blocks is mutually all that each RMSI control resource collection is associated with a synchronization blocks, and two Person is at least space and intends co-located QCLed.

33. terminal device according to claim 32, which is characterized in that the port of each RMSI control resource collection Number is identical with the port number in one synchronization blocks；And the port in each RMSI control resource collection with it is described Port in one synchronization blocks is successively associated according to characterization rules.

34. terminal device according to claim 32, which is characterized in that RMSI control resource collection with it is associated Synchronization blocks are sent in identical time slot respectively.

35. terminal device according to claim 34, which is characterized in that two RMSI control resource collections are located at Comprising there are two in the first two OFDM symbol in synchronization blocks a time slot；

Wherein, the RMSI control resource collection occupies an OFDM symbol respectively, and two RMSI control resource collections are corresponding Wave beam, successively associated with the wave beam of two synchronization blocks in the time slot.

36. terminal device according to claim 34, which is characterized in that the RMSI control resource collection includes at least: First RMSI controls resource collection and the 2nd RMSI controls resource collection；

Wherein, the first RMSI controls resource collection and is located at comprising there are two previous or the first two in synchronization blocks a time slot OFDM symbol；2nd RMSI control resource collection is located at one or two OFDM symbol of the centre in the time slot；

Wherein, the first RMSI control resource collection and the corresponding wave beam of the 2nd RMSI control resource collection, respectively with institute Stating two in time slot corresponding wave beams of synchronization blocks is successively associated.

37. terminal device according to claim 32, which is characterized in that RMSI control resource set with it is associated together Step block is sent in different time slots respectively.

38. the terminal device according to claim 37, which is characterized in that the RMSI control resource collection is located at least one In a OFDM symbol；And resource is controlled comprising continuous n RMSI in the time slot for sending RMSI control resource collection Set, n is positive integer.

39. a kind of communication equipment, comprising: processor and the storage for storing the computer program that can be run on a processor Device,

Wherein, the processor is for when running the computer program, perform claim to require any one of 1-18 the method Step.

40. a kind of storage medium, is stored thereon with computer program, wherein the realization when computer program is executed by processor The step of any one of claim 1-18 the method.