WO2014205739A1

WO2014205739A1 - Data receiving method, sending method and device

Info

Publication number: WO2014205739A1
Application number: PCT/CN2013/078182
Authority: WO
Inventors: 纪鹏宇; 权威; 胡振兴; 张戬
Original assignee: 华为技术有限公司
Priority date: 2013-06-27
Filing date: 2013-06-27
Publication date: 2014-12-31
Also published as: CN104509179B; CN104509179A

Abstract

Provided are a data receiving method, sending method and device. The receiving method comprises: switching a DTX configuration from using a first DTX parameter set to using a second DTX parameter set for discontinuous transmission, according to a received service request, and sending the switched DTX configuration to a UE, wherein the activation state time of a first DTX period in the first DTX parameter set is less than the activation state time of a second DTX period in the second DTX parameter set, or the proportion of the activation state time of the first DTX period in the first DTX period is less than the proportion of the activation state time of the second DTX period in the second DTX period; and receiving uplink data of the UE in the activation state time of the second DTX period. The present invention can meet the QoS requirement of a UE.

Description

Data receiving method, transmitting method and device

Technical field

The embodiments of the present invention relate to communication technologies, and in particular, to a data receiving method, a sending method, and a device.

Background technique

In a communication system, such as a Long Time Evolution (LTE) system, a new carrier type (New Carrier Types, referred to as NCT) cell with a relatively small coverage area can be configured in a traditional macro cell. The NCT cell is a cell that uses a new type of carrier configuration, and adopts a new enhanced physical downlink control channel (ePDCCH).

The base station to which the NCT cell belongs, such as an evolved NodeB (eNB), may be configured as a Discontinuous Transmission (DTX) state, that is, the eNB may alternately be in an active state and an inactive state. The UE may have a function of discontinuous reception (DRX). The eNB turns off the transmitter during the inactive state, and then turns it on during the active state, repeating it according to a certain period. This can reduce the power consumption on the network side to a certain extent. However, due to the discontinuous transmission of the base station, the number of UEs that normally reside in the NCT cell with the DTX function enabled is not much.

If the eNB configures a longer period of DTX for power saving purposes, the eNB cannot send an uplink resource allocation message to the UE because it has been in an inactive state for a long time. At this time, if the UE needs to initiate the uplink service, it must wait for the next DTX activation state of the eNB to send an uplink random access pilot code (preamble) or a scheduling request (Scheduling Request, SR for short) to apply for uplink resources to the eNB, so that The access delay of the UE is relatively large. In addition, in the existing long-period DTX scheme, the duration of each active state is short. If a retransmission occurs or the UE data packet needs to be transmitted multiple times, the UE may not be in an active state of one DTX cycle. The data transmission is completed during the period, so that it must wait until the active state of the next DTX cycle to continue the transmission, resulting in a large data transmission delay. It can be seen that if the eNB performs a relatively long period of DTX, it will be difficult to meet the UE's Qos requirement. Summary of the invention

The embodiments of the present invention provide a data receiving method, a sending method, and a device, which are used to solve the problem that an eNB existing in the prior art cannot meet the QoS requirement of the UE due to performing a long period of DTX.

The first aspect provides a data receiving method, including:

Receiving a service request sent by the user equipment UE;

And performing, according to the service request sent by the UE, the discontinuous transmission DTX configuration by using the first DTX parameter set for discontinuous transmission to use the second DTX parameter set for discontinuous transmission, and the first DTX period of the first DTX parameter set The active state time is less than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is less than the ratio in the first DTX cycle. The ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle;

Transmitting, by the second DTX parameter set, the DTX configuration of the discontinuous transmission to the UE; determining, according to the DTX configuration that uses the second DTX parameter set for discontinuous transmission, an active state time of the second DTX period;

Receiving uplink data sent by the UE during an active state of the second DTX period.

In conjunction with the first aspect, in a first possible implementation manner of the first aspect, the inactive time of the first DTX period is greater than or equal to the inactive time of the second DTX period.

In conjunction with the first aspect or the first possible implementation of the first aspect, in a second possible implementation of the first aspect, the first DTX period is greater than or equal to the second DTX period.

With reference to the first aspect, or the first possible implementation of the first aspect, or the second possible implementation of the first aspect, in a third possible implementation manner of the first aspect, the method further includes: determining The uplink data of the UE is sent, and the DTX configuration is switched from using the second DTX parameter set for discontinuous transmission to using the first DTX parameter set for discontinuous transmission;

Transmitting the DTX configuration for discontinuous transmission using the first DTX parameter set to the

UE o

With reference to the third possible implementation manner of the first aspect, in a fourth possible implementation manner of the first aspect, the DTX configuration that uses the second DTX parameter set to perform discontinuous transmission is sent to the UE , including:

Passing the first radio resource control protocol RRC dedicated signaling or the first paging message or the first broadcast cancellation Sending, to the UE, the DTX configuration that uses the second DTX parameter set to perform discontinuous transmission to the UE, where the DTX configuration that uses the first DTX parameter set for discontinuous transmission is sent to the UE, include:

And transmitting, by the second RRC dedicated signaling or the second paging message or the second broadcast message, the DTX configuration that is discontinuously transmitted by using the first DTX parameter set to the UE.

Combining the first aspect or the first possible implementation of the first aspect or the second possible implementation of the first aspect or the third possible implementation of the first aspect or the fourth possible implementation of the first aspect The implementation manner is the fifth possible implementation manner of the first aspect, the method further includes: establishing an RRC connection with the UE according to the service request;

Receiving the uplink data sent by the UE in the active state of the second DTX period, including:

And receiving, by the RRC connection, uplink data sent by the UE in an active state time of the second DTX period.

Combining the first aspect or the first possible implementation of the first aspect or the second possible implementation of the first aspect or the third possible implementation of the first aspect or the fourth possible implementation of the first aspect In a sixth possible implementation manner of the first aspect, the service request includes a scheduling request or a random access request.

The second aspect provides a data sending method, including:

Sending a service request to the base station;

Receiving, by the base station, using the second discontinuous transmit DTX parameter set for discontinuous transmission

a DTX configuration, where the DTX configuration for performing discontinuous transmission by using the second discontinuous transmit DTX parameter set is used by the base station after the DTX configuration switching by using the first DTX parameter set for discontinuous transmission according to the service request. The DTX configuration, the active state time of the first DTX cycle in the first DTX parameter set is less than the active state time of the second DTX cycle in the second DTX parameter set, or the first DTX cycle in the first DTX parameter set The ratio of the active state time in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle;

Determining an active state time of the second DTX cycle according to the DTX configuration for discontinuous transmission using the second discontinuous transmit DTX parameter set;

And transmitting uplink data to the base station in an active state time of the determined second DTX period. With reference to the second aspect, in a first possible implementation manner of the second aspect, the inactive state time of the first DTX period is greater than or equal to the inactive state time of the second DTX period.

With reference to the second aspect, or the first possible implementation manner of the second aspect, in a second possible implementation manner of the second aspect, the first DTX period is greater than or equal to the second DTX period.

With reference to the second aspect or the first possible implementation manner of the second aspect or the second possible implementation manner of the second aspect, in a third possible implementation manner of the second aspect, in the second DTX cycle After the uplink data is sent to the base station in the active state, the method further includes:

Receiving a DTX configuration sent by the base station to perform discontinuous transmission using the first DTX parameter set.

With reference to the third possible implementation manner of the second aspect, in a fourth possible implementation manner of the second aspect, the receiving, by the base station, the DTX sent by the second discontinuous transmit DTX parameter set for discontinuous transmission Configuration, including:

Receiving, by the base station, a first RRC RRC dedicated signaling or a first paging message or a first broadcast message, where the first RRC dedicated signaling or the first paging message or the first broadcast message includes the DTX configuration for discontinuous transmission using a second discontinuous transmit DTX parameter set;

The DTX configuration sent by the receiving base station to perform discontinuous transmission by using the first DTX parameter set includes:

Receiving, by the base station, a second RRC dedicated signaling or a second paging message or a second broadcast message, where the second RRC dedicated signaling or the second paging message or the second broadcast message includes the adopting the first DTX The parameter set performs a DTX configuration for discontinuous transmission.

Combining the second aspect or the first possible implementation of the second aspect or the second possible implementation of the second aspect or the third possible implementation of the second aspect or the fourth possible implementation of the second aspect In a fifth possible implementation manner of the second aspect, the service request includes a scheduling request or a random access request.

The third aspect provides a data receiving method, including:

Receiving, by the user equipment, a service request sent by the UE for requesting to initiate the first service, and receiving the

a quality of service QoS level of the first service sent by the UE and/or a resource type required by the first service;

Determining from the first DTX configuration of the discontinuous transmission using the at least one discontinuous transmission DTX parameter set according to the QoS level of the first service and/or the resource type required by the first service, The QoS level of the service and/or the type of resource required for the first service DTX configuration for discontinuous transmission with a third DTX parameter set;

Transmitting, to the UE, the DTX configuration that uses the third DTX parameter set for discontinuous transmission; determining, according to the DTX configuration that uses the third DTX parameter set for discontinuous transmission, an active state time of the third DTX cycle;

Receiving uplink data sent by the UE during an active state of the third DTX period.

With reference to the third aspect, in a first possible implementation manner of the third aspect, the receiving, by the UE, a quality of service QoS level of the first service and/or a resource type required by the first service , including:

Receiving, by the UE, a radio resource control protocol RRC connection setup complete message, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

With the third aspect or the first possible implementation manner of the third aspect, in a second possible implementation manner of the third aspect, the sending, by using the third DTX parameter set, the DTX configuration of the discontinuous transmission is sent For the UE, including:

And transmitting, by the RRC dedicated signaling or the paging message or the broadcast message, the DTX configuration that uses the third DTX parameter set for discontinuous transmission to the UE.

With the third aspect or the first possible implementation manner of the third aspect or the second possible implementation manner of the third aspect, in a third possible implementation manner of the third aspect, the receiving user equipment UE sends The service request for requesting to initiate the first service, including:

Receiving, by the user equipment UE, a service request for requesting to initiate at least one first service; and determining, according to the QoS level of the first service and/or a resource type required by the first service, from at least one of the settings Determining a discontinuous transmission using a third DTX parameter set corresponding to a QoS class of the first service and/or a resource type required by the first service, in a DTX configuration in which the discontinuous transmit DTX parameter set performs discontinuous transmission DTX configuration, including:

Determining at least one of the DTX configurations for discontinuous transmission using the at least one DTX parameter set according to the QoS level of the at least one first service and/or the resource type required by the at least one first service Determining, by the QoS class of the at least one first service, and/or the DTX configuration of the resource type required by the at least one first service, using the fourth DTX parameter set for discontinuous transmission;

From the at least one DTX configuration that uses the fourth DTX parameter set for discontinuous transmission, The active state of the DTX cycle is the longest, and the DTX configuration with the shortest inactive state of the DTX cycle using the fourth DTX parameter set for discontinuous transmission is used as the DTX configuration for discontinuous transmission using the third DTX parameter set.

In combination with the third aspect or the first possible implementation of the third aspect or the second possible implementation of the third aspect or the third possible implementation of the third aspect, the fourth possibility in the third aspect In an implementation manner, the method further includes:

If the DTX configuration uses non-continuous transmissions other than the third DTX parameter set, the DTX configuration is switched from non-continuous transmission using the third DTX parameter set to discontinuous transmission using the third DTX parameter set. .

Combining the third aspect or the first possible implementation of the third aspect or the second possible implementation of the third aspect or the third possible implementation of the third aspect or the fourth possible implementation of the third aspect In a fifth possible implementation manner of the third aspect, the at least one DTX parameter set respectively corresponds to different parameter combinations, where the parameter combination includes at least one of a QoS class and a resource type.

Combining the third aspect or the first possible implementation of the third aspect or the second possible implementation of the third aspect or the third possible implementation of the third aspect or the fourth possible implementation of the third aspect The implementation manner or the fifth possible implementation manner of the third aspect, in a sixth possible implementation manner of the third aspect, the service request includes a scheduling request or a random access request.

The fourth aspect provides a data sending method, including:

Sending, to the base station, a service request for requesting to initiate a first service, and transmitting, to the base station, a quality of service QoS level of the first service and/or a resource type required by the first service;

Receiving, by the base station, a DTX configuration for performing discontinuous transmission by using a third DTX parameter set, where the DTX configuration for performing discontinuous transmission by using the third DTX parameter set is that the base station according to the QoS level of the first service and/or Or the required resource type of the first service, the QoS level of the first service and/or the first determined from a set DTX configuration for discontinuous transmission using at least one discontinuous transmission DTX parameter set The DTX configuration corresponding to the resource type required by a service;

Determining an active state time of the third DTX cycle according to the DTX configuration for performing discontinuous transmission using the third DTX parameter set;

And transmitting uplink data to the base station in an active state time of the third DTX period.

With reference to the fourth aspect, in a first possible implementation manner of the fourth aspect, The station sends the quality of service QoS level of the first service and/or the resource type required by the first service, including:

Sending a RRC connection establishment complete message to the base station, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

With reference to the fourth aspect, or the first possible implementation manner of the fourth aspect, in a second possible implementation manner of the fourth aspect, the receiving, by the base station, using a third DTX parameter set for discontinuous transmission DTX configuration, including:

Receiving an RRC dedicated signaling or a paging message or a broadcast message sent by the base station, where the RRC dedicated signaling or paging message or broadcast message includes the DTX configuration that uses the third DTX parameter set for discontinuous transmission.

With reference to the fourth aspect, or the first possible implementation manner of the fourth aspect, or the second possible implementation manner of the fourth aspect, in a third possible implementation manner of the fourth aspect, the service request includes a scheduling request Or random access request.

A fifth aspect provides a data receiving method, including:

Receiving a service request sent by the user equipment UE;

And transmitting, according to the service request, a transmission state from a discontinuous transmission DTX state to a continuous transmission state;

Transmitting, to the UE, the transmission status of the switched continuous transmission state;

Receiving uplink data sent by the UE in the continuous transmission state after the handover.

With reference to the fifth aspect, in a first possible implementation manner of the fifth aspect, the method further includes: determining that the uplink data of the UE is sent;

Switching the transmission state to a DTX state;

Transmitting the transmitted state of the DTX state to the UE.

With reference to the fifth aspect, in a second possible implementation manner of the fifth aspect, the method further includes: when the transmitting state is switched from a DTX state to a continuous transmitting state, starting timing, at the end of timing, The transmitting state is switched from a continuous transmitting state to a DTX state, and the transmitted state of the DTX state after the switching is sent to the UE.

With reference to the second possible implementation manner of the fifth aspect, in a third possible implementation manner of the fifth aspect, the method further includes: If a service request sent by another UE is received before the end of the timer, the timing is restarted. With reference to the fifth aspect or the first possible implementation of the fifth aspect or the second possible implementation of the fifth aspect or the third possible implementation of the fifth aspect, the fourth possibility in the fifth aspect In an implementation manner, the service request includes a scheduling request or a random access request.

The sixth aspect provides a data sending method, including:

Sending a service request to the base station;

Receiving, by the base station, an emission status of the continuous transmission after the base station switches according to the service request, where the transmission status of the base station before handover is a discontinuous transmission DTX state;

Determining a time for transmitting uplink data and/or switching a transmission state to a transmitting state of continuous transmission according to a transmission state of the continuous transmission after the base station is switched;

And transmitting uplink data to the base station according to the determined time of transmitting uplink data and/or in a transmitting state of continuous transmission.

With reference to the sixth aspect, in a first possible implementation manner of the sixth aspect, the method further includes: receiving a transmission state of a DTX state sent by the base station.

A seventh aspect provides a base station, including:

a receiving module, configured to receive a service request sent by the user equipment UE;

a switching module, configured to switch, according to the service request sent by the UE by the receiving module, a discontinuous transmission DTX configuration by using a first DTX parameter set for discontinuous transmission to use a second DTX parameter set for discontinuous transmission, An active state time of the first DTX cycle in the first DTX parameter set is less than an active state time of a second DTX cycle in the second DTX parameter set, or an active state of a first DTX cycle in the first DTX parameter set The ratio of the time in the first DTX period is smaller than the ratio of the active state time of the second DTX period in the second DTX parameter set in the second DTX period; the sending module is configured to switch the switching module to the DTX configuration Transmitting, by using the second DTX parameter set, the DTX configuration of the discontinuous transmission to the UE;

a determining module, configured to determine an active state time of the second DTX cycle according to the DTX configuration for non-continuous transmission by using a second DTX parameter set;

The receiving module is further configured to receive uplink data sent by the UE in an active state time of the second DTX period determined by the determining module.

With reference to the seventh aspect, in a first possible implementation manner of the seventh aspect, the inactive state time of the first DTX period is greater than or equal to the inactive state time of the second DTX period. With reference to the seventh aspect, or the first possible implementation manner of the seventh aspect, in a second possible implementation manner of the seventh aspect, the first DTX period is greater than or equal to the second DTX period.

With reference to the seventh aspect, or the first possible implementation manner of the seventh aspect, or the second possible implementation manner of the seventh aspect, in a third possible implementation manner of the seventh aspect, the switching module is further used to Determining that the uplink data transmission of the UE is completed, and configuring the DTX by using the second

The DTX parameter set performs discontinuous transmission switching to use the first DTX parameter set for discontinuous transmission; the sending module is further configured to: after the switching module switches the DTX configuration that uses the second DTX parameter set for discontinuous transmission The DTX configuration used for discontinuous transmission using the first DTX parameter set is sent to the UE.

With reference to the third possible implementation manner of the seventh aspect, in a fourth possible implementation manner of the seventh aspect, the sending module is specifically configured to use the first radio resource control protocol RRC dedicated signaling or the first paging Sending, by the message or the first broadcast message, the DTX configuration that uses the second DTX parameter set for discontinuous transmission to the UE;

The sending module is specifically configured to send, by using the second RRC dedicated signaling or the second paging message or the second broadcast message, the DTX configuration that is discontinuously transmitted by using the first DTX parameter set to the

UE o

Combining the seventh aspect or the first possible implementation of the seventh aspect or the second possible implementation of the seventh aspect or the third possible implementation of the seventh aspect or the fourth possible implementation of the seventh aspect In a fifth possible implementation manner of the seventh aspect, the base station further includes a connection establishing module;

The connection establishing module is configured to establish an RRC connection with the UE according to the service request received by the receiving module;

The receiving module is specifically configured to receive, by using the RRC connection established by the connection establishing module, uplink data sent by the UE in an active state time of the second DTX period.

Combining the seventh aspect or the first possible implementation of the seventh aspect or the second possible implementation of the seventh aspect or the third possible implementation of the seventh aspect or the fourth possible implementation of the seventh aspect The implementation manner or the fifth possible implementation manner of the seventh aspect, in the sixth possible implementation manner of the seventh aspect, the service request includes a scheduling request or a random access request.

The eighth aspect provides a user equipment, including:

a sending module, configured to send a service request to the base station; a receiving module, configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a second discontinuous transmit DTX parameter set, where the DTX configured to perform discontinuous transmission by using the second discontinuous transmit DTX parameter set is Determining, by the base station, the DTX configuration used after the DTX configuration switching of the discontinuous transmission by using the first DTX parameter set according to the service request sent by the sending module, where the active state time of the first DTX period in the first DTX parameter set is smaller than The active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is smaller in the first DTX cycle than in the second DTX parameter set The ratio of the active state time of the second DTX cycle in the second DTX cycle;

a determining module, configured to determine an active state time of the second DTX cycle according to a DTX configuration received by the receiving module and using a second DTX parameter set for non-continuous transmission;

The sending module is further configured to send uplink data to the base station in an active state time of the second DTX period determined by the determining module.

In conjunction with the eighth aspect, in a first possible implementation manner of the eighth aspect, the inactive state time of the first DTX period is greater than or equal to the inactive state time of the second DTX period.

With reference to the eighth aspect, or the first possible implementation manner of the eighth aspect, in a second possible implementation manner of the eighth aspect, the first DTX period is greater than or equal to the second DTX period.

With reference to the eighth aspect, or the first possible implementation manner of the eighth aspect, or the second possible implementation manner of the eighth aspect, in a third possible implementation manner of the eighth aspect, the receiving module is further used to After the transmitting module sends uplink data to the base station in an active state time of the second DTX period, receiving a DTX configuration sent by the base station to perform discontinuous transmission by using a first DTX parameter set.

With reference to the third possible implementation manner of the eighth aspect, in a fourth possible implementation manner of the eighth aspect, the receiving module is configured to receive, by the base station, a first radio resource control protocol (RRC) dedicated signaling Or the first paging message or the first broadcast message, the first RRC dedicated signaling or the first paging message or the first broadcast message includes a DTX configuration for performing discontinuous transmission using the second DTX parameter set;

The receiving module is specifically configured to receive a second RRC dedicated signaling or a second paging message or a second broadcast message sent by the base station, the second RRC dedicated signaling or the second paging message or the second broadcast message The DTX configuration for non-continuous transmission using the first DTX parameter set is included.

Combining the eighth aspect or the first possible implementation of the eighth aspect or the second aspect of the eighth aspect A possible implementation manner, or a third possible implementation manner of the eighth aspect, or a fourth possible implementation manner of the eighth aspect, in a fifth possible implementation manner of the eighth aspect, the service request includes a scheduling request Or random access request.

A ninth aspect provides a base station, including:

a receiving module, configured to receive a service request sent by the user equipment UE for requesting to initiate a first service, and receive a quality of service QoS level of the first service sent by the UE and/or required by the first service Resource Type;

a determining module, configured to perform DTX of discontinuous transmission from the set using at least one discontinuous transmission DTX parameter set according to a QoS class of the first service received by the receiving module and/or a resource type required by the first service In the configuration, determining a DTX configuration that uses the third DTX parameter set to perform discontinuous transmission corresponding to the QoS level of the first service and/or the resource type required by the first service, and a sending module, configured to: Determining, by the module, the DTX configuration that uses the third DTX parameter set for discontinuous transmission is sent to the UE;

The determining module is further configured to determine an active state time of the third DTX cycle according to the DTX configuration that performs the discontinuous transmission by using the third DTX parameter set;

The receiving module is further configured to receive uplink data sent by the UE in an active state time of a third DTX period determined by the determining module.

With reference to the ninth aspect, in a first possible implementation manner of the ninth aspect, the receiving module is configured to receive a radio resource control protocol RRC connection setup complete message that is sent by the UE, where the RRC connection setup complete message includes The QoS level of the first service and/or the resource type required by the first service.

With reference to the ninth aspect, or the first possible implementation manner of the ninth aspect, in the second possible implementation manner of the ninth aspect, the sending module is specifically configured to use RRC dedicated signaling or a paging message or a broadcast message. And transmitting, to the UE, the DTX configuration that uses the third DTX parameter set for discontinuous transmission.

With reference to the ninth aspect, or the first possible implementation manner of the ninth aspect, or the second possible implementation manner of the ninth aspect, in the third possible implementation manner of the ninth aspect, the receiving module is specifically used Receiving, by the UE, a service request for requesting to initiate the at least one first service; the determining module is specifically configured to: according to the QoS level of the at least one first service and/or the at least one first service The type of resource required, from the setting of using at least one discontinuous transmission DTX Determining, in a DTX configuration in which the parameter set performs discontinuous transmission, determining, by using the fourth DTX parameter set, the at least one QoS level corresponding to the at least one first service and/or the resource type required by the at least one first service The continuously transmitting DTX configuration, in the DTX configuration in which the at least one discontinuous transmission is performed using the fourth DTX parameter set, determining that the active state time of the DTX cycle is the longest, and the fourth DTX is the shortest inactive time of the DTX cycle. The parameter set performs a DTX configuration of discontinuous transmission as the DTX configuration for discontinuous transmission using the third DTX parameter set.

With reference to the ninth aspect or the first possible implementation of the ninth aspect or the second possible implementation of the ninth aspect or the third possible implementation of the ninth aspect, the fourth possibility in the ninth aspect In an implementation manner, the determining module is further configured to: when the DTX configuration uses the third DTX parameter set to perform discontinuous transmission, the DTX configuration is performed by using a non-continuous transmission switch that is not the third DTX parameter set. Discontinuous transmission is performed for the third DTX parameter set.

Combining the ninth aspect or the first possible implementation of the ninth aspect or the second possible implementation of the ninth aspect or the third possible implementation of the ninth aspect or the fourth possible implementation of the ninth aspect In a fifth possible implementation manner of the ninth aspect, the at least one DTX parameter set respectively corresponds to different parameter combinations, and the parameter combination includes at least one of a QoS class and a resource type.

Combining the ninth aspect or the first possible implementation of the ninth aspect or the second possible implementation of the ninth aspect or the third possible implementation of the ninth aspect or the fourth possible implementation of the ninth aspect In a sixth possible implementation manner of the ninth aspect, the service request includes a scheduling request or a random access request.

A tenth aspect provides a user equipment, including:

a sending module, configured to send, to the base station, a service request for requesting to initiate the first service, and send, to the base station, a quality of service QoS level of the first service and/or a resource type required by the first service;

a receiving module, configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a third discontinuous transmit DTX parameter set, where the DTX configuration that uses the third DTX parameter set for discontinuous transmission is performed by the base station according to the a QoS level of the first service and/or a required resource type of the first service, and a QoS level of the first service determined from a set DTX configuration for discontinuous transmission using at least one DTX parameter set / or a DTX configuration corresponding to the resource type required by the first service; a determining module, configured to determine an active state time of the third DTX cycle according to the DTX configuration received by the receiving module and using the third DTX parameter set for discontinuous transmission;

The sending module is further configured to send uplink data to the base station in an active state time of the third DTX period determined by the determining module.

With the tenth aspect, in a first possible implementation manner of the tenth aspect, the sending module is configured to send a radio resource control protocol RRC connection setup complete message to the base station, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

With reference to the tenth aspect, or the first possible implementation manner of the tenth aspect, in a second possible implementation manner of the tenth aspect, the receiving module is specifically configured to receive RRC dedicated signaling sent by the base station or a paging message or a broadcast message, the RRC dedicated signaling or paging message or broadcast message including the DTX configuration for discontinuous transmission using the third DTX parameter set.

With reference to the tenth aspect, or the first possible implementation manner of the tenth aspect, or the second possible implementation manner of the tenth aspect, in a third possible implementation manner of the tenth aspect, the service request includes a scheduling request Or random access request.

The eleventh aspect provides a base station, including:

a switching module, configured to switch a transmission state from a discontinuous transmission DTX state to a continuous transmission state according to the service request received by the receiving module;

a sending module, configured to send, to the UE, a transmission status of the continuous transmission state after the switching module is switched;

The receiving module is further configured to receive uplink data sent by the UE in a continuous transmission state after the switching module is switched.

With reference to the eleventh aspect, in a first possible implementation manner of the eleventh aspect, the base station further includes a determining module;

The determining module is configured to determine that the uplink data of the UE is sent;

The switching module is further configured to: after the determining module determines that the uplink data of the UE is sent, switch the transmitting state to a DTX state;

The sending module is further configured to send, to the UE, a transmit status of the DTX state after the switching module is switched. With reference to the eleventh aspect, in a second possible implementation manner of the eleventh aspect, the base station further includes: a timing module, configured to start timing when the transmitting state is switched from a DTX state to a continuous transmitting state;

The switching module is further configured to switch the transmitting state from a continuous transmitting state to a DTX state when the timing module ends timing;

The sending module is configured to send, to the UE, a transmit status of the DTX state after the switching module is switched.

With reference to the second possible implementation manner of the eleventh aspect, in a third possible implementation manner of the eleventh aspect, the timing module is further configured to: before the receiving module receives other UEs before timing ends When the business request is sent, the timing is restarted.

With reference to the eleventh aspect or the first possible implementation of the eleventh aspect or the second possible implementation of the eleventh aspect or the third possible implementation of the eleventh aspect, in an eleventh aspect In a fourth possible implementation manner, the service request includes a scheduling request or a random access request.

A twelfth aspect provides a user equipment, including:

a sending module, configured to send a service request to the base station;

a receiving module, configured to receive a transmission status of the continuous transmission that is sent by the base station after the base station is switched according to the service request, where a transmission status of the base station before handover is a discontinuous transmission DTX state;

a determining module, configured to determine a time for transmitting uplink data and/or to switch a transmitting state to a transmitting state of continuous transmission according to a transmitting state of the continuous transmission after the base station switching received by the receiving module;

The sending module is further configured to send uplink data to the base station according to a time for transmitting uplink data determined by the determining module and/or in a transmitting state of continuous transmission.

In conjunction with the twelfth aspect, in a first possible implementation of the twelfth aspect, the receiving module is further configured to receive a transmit state of a DTX state sent by the base station.

A thirteenth aspect provides a base station, including:

a receiver, configured to receive a service request sent by the user equipment UE;

a processor, configured to switch, according to the service request sent by the UE by the receiver, a discontinuous transmission DTX configuration by using a first DTX parameter set for discontinuous transmission to use a second DTX parameter set for discontinuous transmission, Active state time of the first DTX cycle in the first DTX parameter set The active state time less than the second DTX period in the second DTX parameter set, or the active state time of the first DTX period in the first DTX parameter set is smaller than the second DTX parameter in the first DTX period The ratio of the active state time of the concentrated second DTX cycle in the second DTX cycle; the transmitter, the DTX for discontinuous transmission using the second DTX parameter set used after the processor switches the DTX configuration The configuration is sent to the UE;

The processor is further configured to determine an active state time of the second DTX cycle according to the DTX configuration that performs discontinuous transmission by using a second DTX parameter set;

The receiver is further configured to receive uplink data sent by the UE in an active state time of the second DTX period determined by the processor.

A fourteenth aspect provides a user equipment, including:

a transmitter, configured to send a service request to the base station;

a receiver, configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a second discontinuous transmit DTX parameter set, where the DTX configured to perform discontinuous transmission by using the second discontinuous transmit DTX parameter set is Determining, by the base station, the DTX configuration used after the DTX configuration switching of the discontinuous transmission by using the first DTX parameter set according to the service request sent by the sending module, where the active state time of the first DTX period in the first DTX parameter set is smaller than The active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is smaller in the first DTX cycle than in the second DTX parameter set The ratio of the active state time of the second DTX cycle in the second DTX cycle;

a processor, configured to determine an active state time of the second DTX cycle according to a DTX configuration received by the receiver and configured to perform discontinuous transmission by using a second DTX parameter set;

The transmitter is further configured to send uplink data to the base station within an active state time of the second DTX period determined by the processor.

A fifteenth aspect provides a base station, including:

a receiver, configured to receive a service request sent by the user equipment UE for requesting to initiate a first service, and receive a quality of service QoS level of the first service sent by the UE and/or required by the first service Resource Type;

a processor, configured to perform DTX of discontinuous transmission from the set of at least one discontinuous transmit DTX parameter set according to a QoS level of the first service received by the receiver and/or a resource type required by the first service In the configuration, determining a QoS level with the first service and/or the first service a DTX configuration for the discontinuous transmission using the third DTX parameter set corresponding to the required resource type, and a transmitter, configured to send, to the processor, the DTX configuration determined by the processor to perform discontinuous transmission by using the third DTX parameter set UE;

The processor is further configured to determine an active state time of the third DTX cycle according to the DTX configuration for performing discontinuous transmission by using the third DTX parameter set;

The receiver is further configured to receive uplink data sent by the UE in an active state time of a third DTX period determined by the processor.

A sixteenth aspect provides a user equipment, including:

a transmitter, configured to send, to the base station, a service request for requesting to initiate a first service, and send, to the base station, a quality of service QoS level of the first service and/or a resource type required by the first service;

a receiver, configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a third discontinuous transmit DTX parameter set, where the DTX configuration that uses the third DTX parameter set for discontinuous transmission is performed by the base station according to the a QoS level of the first service and/or a required resource type of the first service, and a QoS level of the first service determined from a set DTX configuration for discontinuous transmission using at least one DTX parameter set / or a DTX configuration corresponding to the resource type required by the first service;

a processor, configured to determine an active state time of the third DTX cycle according to the DTX configuration received by the receiver and using the third DTX parameter set for discontinuous transmission;

The transmitter is further configured to send uplink data to the base station within an active state time of the third DTX period determined by the processor.

A seventeenth aspect provides a base station, including:

a processor, configured to switch a transmission state from a discontinuous transmission DTX state to a continuous transmission state according to the service request received by the receiver;

a transmitter, configured to send, to the UE, a transmission status of the continuous transmission state after the processor is switched;

The receiver is further configured to receive uplink data sent by the UE in a continuous transmission state after the processor is switched.

The eighteenth aspect provides a user equipment, including: a transmitter, configured to send a service request to the base station;

a receiver, configured to receive, by the base station, a transmission status of the continuous transmission after the base station switches according to the service request, where the transmission status of the base station before handover is a discontinuous transmission DTX status;

a processor, configured to determine a time for transmitting uplink data and/or to switch a transmission state to a continuously transmitted transmission state according to an emission state of the continuous transmission after the base station switching received by the receiver;

The transmitter is further configured to transmit uplink data to the base station according to a time when the uplink data is transmitted by the processor and/or in a transmission state of the continuous transmission.

The data receiving method, the transmitting method, and the base station are provided by setting two DTX parameter sets, wherein the first parameter set includes an active state time of a DTX cycle shorter, and the second parameter set includes an activated state of the DTX cycle. The time is longer. When no UE initiates the service, the base station performs DTX by using the parameters of the first parameter set, so that the base station can save power; after receiving the service request of the UE, by changing the DTX configuration to the configuration of the second parameter set, The base station can extend the time in the active state when the UE has the service requirement, and reduce the time in the inactive state, so that the UE can access the cell to obtain the service in time, thereby reducing the delay of the UE accessing or performing data transmission, and solving the problem. The problem that the base station performs a relatively long period of DTX cannot meet the QoS requirements of the UE.

On the other hand, the data receiving method, the sending method, and the base station are provided, and at least one DTX parameter set is set for the service quality level and/or the required resource type of different services, and after receiving the service request sent by the UE, sending according to the UE Determining the quality of service level and/or the type of resource required for the service being carried out, determining the quality of service level and/or required for the service requested by the UE from the DTX configuration for discontinuous transmission using at least one DTX parameter set Corresponding to the DTX configuration of the discontinuous transmission using the third DTX parameter set corresponding to the resource type, and then receiving the uplink data of the UE in the active state time of determining the third DTX period according to the DTX configuration for discontinuous transmission using the third DTX parameter set. Therefore, the base station can better adjust the time ratio of the active state and the inactive state according to different service requirements of the UE, so that the UE can access the cell to obtain the service in time, and reduce the delay of the UE accessing or performing data transmission. It solves the problem that the base station cannot perform the Qo of the UE due to the relatively long period of DTX being executed by the base station. The problem of S demand.

In another aspect, the data receiving method, the sending method, and the base station are provided, and when the UE has a service requirement, the base station switches the transmitting state from the DTX state to the continuous transmitting state, so that the UE can access the network in time. The cell obtains the service, reduces the delay of the UE accessing or performing the data transmission, and solves the problem that the base station performs the relatively long period of DTX, which cannot meet the QoS requirement of the UE, thereby ensuring the transmission or connection of the foregoing data of the UE. In. BRIEF DESCRIPTION OF THE DRAWINGS In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, a brief description of the drawings used in the embodiments or the prior art description will be briefly described below. The drawings are some embodiments of the present invention, and those skilled in the art can obtain other drawings based on these drawings without any inventive labor.

FIG. 1 is a flowchart of a data receiving method according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a DTX mechanism using a first DTX parameter set according to an embodiment of the present invention; FIG. 3 is a schematic diagram of a DTX mechanism using a second DTX parameter set according to an embodiment of the present invention; FIG. A flow chart of another data receiving method;

FIG. 5 is a flowchart of still another data receiving method according to an embodiment of the present invention;

FIG. 6 is a flowchart of a data sending method according to an embodiment of the present invention;

FIG. 7 is a flowchart of still another data receiving method according to an embodiment of the present invention;

FIG. 8 is a flowchart of another data sending method according to an embodiment of the present invention;

FIG. 9 is a flowchart of still another data receiving method according to an embodiment of the present invention;

FIG. 10 is a flowchart of still another data sending method according to an embodiment of the present invention;

FIG. 1 is a schematic structural diagram of a base station according to an embodiment of the present disclosure;

FIG. 12 is a schematic structural diagram of another base station according to an embodiment of the present disclosure;

FIG. 13 is a schematic structural diagram of a UE according to an embodiment of the present disclosure;

FIG. 14 is a schematic structural diagram of another UE according to an embodiment of the present disclosure;

FIG. 15 is a schematic structural diagram of still another base station according to an embodiment of the present disclosure;

FIG. 16 is a schematic structural diagram of still another base station according to an embodiment of the present disclosure;

FIG. 17 is a schematic structural diagram of still another UE according to an embodiment of the present disclosure;

FIG. 18 is a schematic structural diagram of still another UE according to an embodiment of the present disclosure;

FIG. 19 is a schematic structural diagram of still another base station according to an embodiment of the present disclosure;

FIG. 20 is a schematic structural diagram of still another base station according to an embodiment of the present disclosure;

FIG. 21 is a schematic structural diagram of still another UE according to an embodiment of the present disclosure; FIG. 22 is a schematic structural diagram of still another UE according to an embodiment of the present invention.

detailed description

The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is a partial embodiment of the invention, and not all of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative efforts are within the scope of the present invention.

First, the base station to which the NTC cell belongs can be configured to be in the DTX state, that is, the base station to which the NTC cell belongs can be alternately in the active state and the inactive state, and can change the time when the base station to which the NTC cell belongs is in the active state and the inactive state. The purpose of changing the effect that the base station to which the NTC cell belongs is serving the UE is achieved. Therefore, the following embodiments of the present invention are applicable to the NTC cell, but are not limited to the NTC cell.

FIG. 1 is a flowchart of a data receiving method according to an embodiment of the present invention. As shown in FIG. 1, the method includes:

Step 101: Receive a service request sent by the UE.

Step 102: Switch the DTX configuration from the discontinuous transmission by using the first DTX parameter set to the discontinuous transmission by using the second DTX parameter set according to the service request sent by the UE.

Step 103: Send the DTX configuration that uses the second DTX parameter set for discontinuous transmission to the UE.

In this embodiment, the DTX parameter set may include at least one of the following parameters: a length of a DTX cycle, an active state time of a DTX cycle, and an inactive state time of a DTX cycle. For example, the first DTX parameter set may include at least one of the following parameters: a first DTX period, an active state time of the first DTX cycle, and an inactive state time in the first DTX cycle; the second DTX The parameter set may include at least one of the following parameters: a second DTX period, an active state time of the second DTX cycle, and an inactive state time in the second DTX cycle.

The active state time of the first DTX cycle in the first DTX parameter set is smaller than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is The ratio in the first DTX period is less than the ratio of the active state time of the second DTX period in the second DTX parameter set in the second DTX period, such that when the base station is from the first DTX When the parameter set is changed to use the second DTX parameter set to perform DTX, the time in the active state can be extended, and the time in the inactive state can be reduced, so that the UE can access the cell in time to obtain the service, and the UE access or data transmission is reduced. The delay solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirements of the UE.

Further optionally, the inactive state time of the first DTX cycle in the first DTX parameter set may be greater than or equal to the inactive state time of the second DTX cycle in the second DTX parameter set. When the inactive state time of the first DTX cycle in the first DTX parameter set is greater than the inactive state time of the second DTX cycle in the second DTX parameter set, when the base station changes from the first DTX parameter set to the first When the DTX parameter set performs DTX, the time in the inactive state can be further reduced, and the UE can access the cell to obtain the service in time, thereby reducing the delay of the UE accessing or performing data transmission, and solving the problem that the base station performs relatively long. The DTX of the period brings about the problem that the QoS requirements of the UE cannot be met.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In the case that the first DTX period is greater than the second DTX period, when the base station changes from the first DTX parameter set to the second DTX parameter set to perform DTX, the time in the inactive state may be further reduced, The UE can be enabled to access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

In an example, the active state time of the first DTX cycle in the first DTX parameter set may be equal to the active state time of the second DTX cycle in the second DTX parameter set, and the first DTX parameter set A DTX period is greater than a second DTX period in the second DTX parameter set.

In one example, the description of the active state time of the first DTX cycle in the first DTX parameter set is less than the active state time of the second DTX cycle in the second DTX parameter set may be replaced by:

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. For example, a DTX mechanism using the first DTX parameter set is shown in Figure 2, and a DTX mechanism using the second DTX parameter set is shown in Figure 3.

When the DTX of the base station is configured to use the first DTX parameter set for discontinuous transmission, the duration of the inactive state (ie, the transmitter is turned off) in each DTX period is relatively long, and in each DTX period. The duration of the active state (ie, the transmitter is turned on) is short. Therefore, for example, it can be applied to a scenario in which no UE needs to initiate a service in an NCT cell. When the DTX configuration of the base station uses the second DTX parameter set for discontinuous transmission, the active state (ie, the transmitter is turned on) is longer in each DTX period, and is inactive in each DTX period (ie, The duration of the transmitter is short. Therefore, for example, it can be applied to a scenario in which an UE needs to initiate a service in an NCT cell.

After the base station receives the service request sent by the UE in the NCT cell, if the current DTX configuration of the base station uses the second DTX parameter set for discontinuous transmission, the current DTX configuration may be maintained, if the current DTX configuration is the first The DTX parameter set performs discontinuous transmission. In order to enable the UE to perform services in time to meet the quality of service (QoS) requirements of the related services, the base station switches the DTX configuration from the discontinuous transmission using the first DTX parameter set to the second DTX parameter set. The discontinuous transmission is performed so that the base station can be in an active state for a long time in each DTX cycle. In addition, in order to enable the UE to synchronize with the base station side, the base station needs to notify the UE of the DTX configuration synchronization of the discontinuous transmission using the second DTX parameter set after the handover, so that the UE can send the base station to the base station when the base station is in the active state. Upstream data.

Optionally, the base station may not only send the switched DTX configuration that uses the second DTX parameter set for discontinuous transmission to the UE that initiates the service request, but also may perform the DTX configuration after the handover using the second DTX parameter set for discontinuous transmission. The synchronization is notified to other UEs in the NCT cell, so that other UEs can also initiate a service request to the base station when the base station is in an active state.

Optionally, the base station may perform the DTX configuration of the discontinuous transmission by using the second DTX parameter set after the handover by using a radio resource control protocol (Radio Resource Control, RRC for short) dedicated signaling or a paging message or a broadcast message. Send to the UE. For convenience of distinguishing, the RRC dedicated signaling or paging message or broadcast message used in the DTX configuration for notifying the UE to be discontinuously transmitted using the second DTX parameter set after the UE is notified of the handover is referred to as the first RRC dedicated signaling or the first. a paging message or a first broadcast message, that is, the base station may perform the discontinuous transmission of the DTX by using the second DTX parameter set by using the first RRC dedicated signaling or the first paging message or the first broadcast message. The configuration is sent to the UE.

Step 104: Determine an active state time of the second DTX cycle according to the DTX configuration that performs discontinuous transmission by using a second DTX parameter set.

Step 105: Receive uplink data sent by the UE in an active state time of the second DTX period. After the base station switches the DTX configuration from the discontinuous transmission using the first DTX parameter set to the discontinuous transmission using the second DTX parameter set, the DTX configuration may be determined according to the DTX configuration using the second DTX parameter set for discontinuous transmission. The active state time of the second DTX cycle. In this way, after the base station sends the switched DTX configuration that uses the second DTX parameter set to perform the discontinuous transmission to the UE, the UE may send the uplink data to the base station when the base station is in the active state; correspondingly, the base station is in the second The uplink data sent by the UE is received during the active state of the DTX cycle.

In an optional implementation manner, after receiving the service request of the UE, the base station establishes an RRC connection with the UE according to the service request. Based on this, the receiving, by the base station, the uplink data sent by the UE in the active state of the second DTX period includes: receiving, by the base station, the UE by using the RRC connection, in an active state time of the second DTX period. Upstream data. For a process in which the eNB establishes an RRC connection with the UE according to the service request of the UE, refer to the related art, and details are not described in this embodiment.

At this time, the base station adopts a second DTX cycle in the second DTX parameter set, and the time in the active state is the active state time of the second DTX cycle specified in the second DTX parameter set, and the time in the inactive state is the The inactive state time of the second DTX period specified in the two DTX parameter sets. Since the active state time of the second DTX cycle is longer and the non-active state time is shorter, the base station is in the active state for a longer period of time and the inactive time is shorter. Based on this, if the UE needs to initiate random access, even if it needs to wait for the next time the base station is in the DTX active state to send a random access pilot (preamble) code, since the base station is in an inactive state for a short time, the first parameter is adopted. The DTX configuration for non-continuous transmission reduces the delay of UE access. If data retransmission occurs or the data packet that the UE needs to transmit is relatively large, in the DTX configuration in which the first parameter set is used for discontinuous transmission, since the time when the base station is in the active state is relatively short, it may not be completed during an active state, resulting in Large data transmission delay; in this embodiment, since the time when the base station is in the inactive state is short and the active state is longer, the larger data or data retransmission can be experienced during the less active state. This is done, reducing the data transfer delay. It can be seen that the method provided in this embodiment can reduce the delay of the UE accessing or transmitting data, and is beneficial to satisfy the QoS requirement of the UE.

Based on the foregoing example, the service request sent by the UE in this embodiment may include a random access request, or may include a scheduling request (Scheduling Request, SR for short) of the resource for data transmission, but is not limited thereto.

FIG. 4 is a flowchart of another data receiving method according to an embodiment of the present invention. As shown in FIG. 4, the method includes: Step 401: Receive a service request sent by the UE.

Step 402: Switch the DTX configuration from the discontinuous transmission by using the first DTX parameter set to the discontinuous transmission by using the second DTX parameter set according to the service request sent by the UE.

Step 403: Send the DTX configuration that uses the second DTX parameter set for discontinuous transmission to the UE.

In this embodiment, the DTX parameter set may include at least one of the following parameters: a length of a DTX cycle, an active state time of a DTX cycle, and an inactive state time of a DTX cycle. For example, the first DTX parameter set may include at least one of the following parameters: a first DTX period, an active state time of the first DTX cycle, and an inactive state time of the first DTX cycle; the second DTX parameter The set may include at least one of the following parameters: a second DTX period, an active state time of the second DTX cycle, and an inactive state time of the second DTX cycle.

The active state time of the first DTX cycle in the first DTX parameter set is smaller than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is The ratio in the first DTX period is smaller than the ratio of the active state time of the second DTX period in the second DTX parameter set in the second DTX period, such that when the base station changes from the first DTX parameter set to the second DTX parameter set When the DTX is executed, the time in the active state can be extended, and the time in the inactive state can be reduced, so that the UE can access the cell in time to obtain the service, and the delay of the UE accessing or data transmission is reduced, and the base station is executed. Compared with the long-cycle DTX, the problem of not meeting the QoS requirements of the UE is brought about.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In the case that the first DTX period is greater than the second DTX period, when the base station changes from the first DTX parameter set to the second DTX parameter set to perform DTX, the inactive state may be further reduced. The time can enable the UE to access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE. .

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. Step 404: Determine an active state time of the second DTX cycle according to the DTX configuration that performs discontinuous transmission by using a second DTX parameter set.

Step 405: Receive uplink data sent by the UE in an active state time of the second DTX period.

For the step 401-step 405, refer to step 101-step 105 in the above embodiment, and details are not described herein again.

Step 406: Determine that the uplink data of the UE is sent, and switch the DTX configuration by using a second DTX parameter set for discontinuous transmission to use the first DTX parameter set for discontinuous transmission, and The DTX configuration in which the first DTX parameter set performs discontinuous transmission is sent to the UE.

The base station can determine whether the uplink data of the UE is sent in different manners. For example, after the uplink data sent by the UE is correctly received by the base station, the base station may feed back an acknowledgement (ACK) message to the UE, and the base station may determine that the uplink data transmission of the UE is completed. Alternatively, after transmitting the uplink data, the UE may send an indication information to the base station to notify the base station that the uplink data transmission ends, and the base station may determine, according to the indication information sent by the UE, that the uplink data transmission of the UE ends.

In addition, taking the NCT cell as an example, other UEs in the NTC cell may also initiate a service request at any time when the base station is in an active state. Based on this, the end of the uplink data transmission of the UE may be represented by all the UEs in the NCT cell that are in the RRC connection state and perform data transmission, and the UE may send one or more uplink data. After determining that the uplink data transmission of the UE is completed, the base station switches the discontinuous transmission by using the second DTX parameter set to the discontinuous transmission by using the first DTX parameter set by using the DTX configuration, and by using the longer inactive state time, A short active state is used to save power. Correspondingly, in order to enable the UE to synchronize with the base station, the base station also needs to send the DTX configuration after the re-switching using the first DTX parameter set for discontinuous transmission to the UE. Optionally, the base station may send, by using the second RRC dedicated signaling or the second paging message or the second broadcast message, the DTX configuration that is discontinuously transmitted by using the first DTX parameter set to the UE.

FIG. 5 is a flowchart of still another data receiving method according to an embodiment of the present invention. As shown in FIG. 5, the method includes:

Step 51: The UE initiates a service to the base station. Specifically, the UE sends a random access pilot code or SR to the base station.

In this step, if the DTX configuration of the base station is using the first DTX parameter set for discontinuous transmission, and the base station is in the active state, the UE may send a random access pilot code or SR to the base station, where the SR is used to indicate The UE needs to initiate a service; otherwise, the UE needs to wait until the base station enters the active state for the next time to send a random access pilot or SR request to the base station.

Step 52: After receiving the random access pilot code or SR sent by the UE, the base station establishes an RRC connection with the UE.

Step 53: The base station switches the DTX configuration from the discontinuous transmission by using the first DTX parameter set to the discontinuous transmission by using the second DTX parameter set, that is, by using a shorter inactive state duration and a longer active state duration. The Qos demand of the UE's business.

Optionally, the base station may send the DTX configuration of the discontinuous transmission by using the second DTX parameter set to the UE in the cell by using a broadcast message or the like, so that other UEs in the cell may also initiate services if they also need to initiate services. The base station initiates a service request to the base station during the active state, which increases the scheduling opportunities of more UEs from the cell level.

Step 54: The UE enters an RRC connection state, initiates a service normally, and sends uplink data to the base station. Step 55: After the uplink data of the UE is sent, the base station releases the RRC connection of the UE in the connected state, and returns the UE to the RRC idle state.

Step 56: The base station switches the DTX configuration from the discontinuous transmission by using the second DTX parameter set to the discontinuous transmission by using the first DTX parameter set, that is, by using a longer inactive state duration and a shorter active state duration. Power saving. Optionally, if the base station sends a broadcast message or the like to the UE in the cell to indicate the change of the DTX configuration, the base station may send the broadcast message or the like to the UE in the cell to indicate the DTX configuration. Change it again.

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. In this embodiment, by setting two DTX parameter sets, the base station can extend the time of the active state by changing the DTX configuration when the UE has a service requirement, and reduce the time in the inactive state, so that the UE can enter the cell in time. The service reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

In this embodiment, in the embodiment shown in FIG. 1 or FIG. 4 or FIG. 5, the base station may set a timer for timing the active time of the DTX cycle, and when the timer expires, the base station enters the inactive state. state. Optionally, the base station may extend the time in the active state by using a timer. For example, if the base station receives the service request of the UE during the active state, the base station may be restarted by the restart timer to restart the active state. The timer expires and then enters the inactive state.

FIG. 6 is a flowchart of a data sending method according to an embodiment of the present invention. As shown in FIG. 6, the method includes:

Step 601: Send a service request to the base station.

Step 602: Receive, by using, the second DTX parameter set sent by the base station to perform discontinuous transmission.

a DTX configuration, where the DTX configuration using the second DTX parameter set for discontinuous transmission is a DTX configuration used by the base station to switch from a DTX configuration using a first DTX parameter set for discontinuous transmission according to the service request, The active state time of the first DTX cycle in the first DTX parameter set is less than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is The ratio in the first DTX cycle is less than the second DTX The ratio of the active state time of the second DTX cycle in the parameter set in the second DTX cycle. In an example, the active state time of the first DTX cycle in the first DTX parameter set may be equal to the active state time of the second DTX cycle in the second DTX parameter set, and the first DTX parameter set A DTX period is greater than a second DTX period in the second DTX parameter set.

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. Step 603: Determine an active state time of the second DTX cycle according to the DTX configuration that uses the second DTX parameter set to perform discontinuous transmission.

Step 604: Send uplink data to the base station in an active state of the determined second DTX period.

Further optionally, the inactive state time of the first DTX cycle may be greater than or equal to the inactive state time of the second DTX cycle.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. Further, after the foregoing data is sent to the base station in the active state of the second DTX period, the method further includes: receiving, by the base station, a DTX configuration that is sent by the base station by using the first DTX parameter set, that is, the receiving base station sends the The changed DTX configuration, the re-modified DTX configuration uses the first DTX parameter set for discontinuous transmission.

Optionally, the receiving, by the base station, the DTX configuration that uses the second DTX parameter set to perform the discontinuous transmission includes: receiving the first RRC dedicated signaling or the first paging message or the first broadcast message sent by the base station The first RRC dedicated signaling or the first paging message or the first broadcast message includes the DTX configuration that uses the second DTX parameter set for discontinuous transmission.

Correspondingly, the receiving, by the base station, the DTX configuration that uses the first DTX parameter set to perform the discontinuous transmission includes: receiving the second RRC dedicated signaling or the second paging message or the second broadcast message sent by the base station, The second RRC dedicated signaling or the second paging message or the second broadcast message includes the DTX configuration that uses the first DTX parameter set for discontinuous transmission.

This embodiment is a description of the data receiving method provided by the embodiment shown in FIG. 1 or FIG. 4 or FIG. 5, and details are not described herein again. Herein, the service request sent by the UE includes an SR or a random access request.

In this embodiment, the base station sets two DTX parameter sets, where the first parameter set includes a DTX cycle with an active state time shorter, and the second parameter set includes a DTX cycle with an active state time longer, and the UE has When the service is requested, the base station switches the DTX configuration, so that the second parameter set is used to perform DTX, the time in the active state is extended, the time in the inactive state is reduced, and the switched DTX configuration is provided to the UE, and after receiving the handover, the UE receives the handover. After the DTX is configured, it synchronizes with the base station, and sends uplink data to the base station in an active state time of the second DTX period of the second DTX parameter set, and can access the cell to obtain the service in time, thereby reducing the time when the UE accesses or performs data transmission. The delay solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirements of the UE.

FIG. 7 is a flowchart of still another data receiving method according to an embodiment of the present invention. As shown in FIG. 7, the method includes:

Step 701: Receive a service request sent by the UE to request to initiate a first service, and receive a QoS level of the first service and/or a resource type required by the first service sent by the UE.

Step 702: Determine, according to the QoS level of the first service, and/or the resource type required by the first service, from the set DTX configuration that uses the at least one DTX parameter set to perform discontinuous transmission. The DTX configuration for the discontinuous transmission using the third DTX parameter set corresponding to the QoS class of the service and/or the resource type required by the first service.

Step 703: Send the DTX configuration that uses the third DTX parameter set to perform discontinuous transmission to the UE.

Step 704: Determine, according to the DTX configuration that uses the third DTX parameter set for discontinuous transmission, an active state time of the third DTX cycle.

Step 705: Receive uplink data sent by the UE in an active state time of the third DTX period.

Generally, when the UE initiates different services, the sensitivity to the delay and the required QoS level are different. Therefore, in this embodiment, the services of different QoS levels initiated by the UE and/or resource types required by the service are set. At least one DTX parameter set. The at least one DTX parameter set respectively corresponds to different parameter combinations, and the parameter combination includes at least one of a QoS class and a resource type. Table 1 shows the correspondence between the QoS levels of different services (that is, the priorities corresponding to the services in Table 1) and the resource types required by different services, but is not limited thereto. The resource types in Table 1 mainly include Guaranteed Bit Rate (GBR) type and non-GBR. (Non-GBR) type, but not limited to this.

Table 1

For different QoS classes shown in Table 1 and/or services requiring different resource types, the base station can set a DTX parameter set for each service. The base station can set different DTX parameter sets for different services according to the QoS class of the service. For example, the base station can set the DTX parameter set with the longest active state and the shortest inactive state for the service with priority 1. The active state duration is set to be shorter than the priority 1 service for the service with priority 2. Short, inactive state, slightly longer DTX parameter set, and so on. Alternatively, the base station can set different DTX parameter sets for different services according to the resource type required by the service and the QoS class of the service. For example, the base station can set the DTX parameter set with the longest active state and the shortest inactive state for the service of the GBR and the service with the priority of 1, and can be a non-GBR service with the priority of 1. Set the active state duration to be slightly shorter than the priority 1 traffic, and the inactive state is slightly longer than the DTX parameter set.

Specifically, when the UE needs to initiate a service, the UE sends a service request to the base station. This example takes the UE requesting to initiate the first service as an example. For example, if the UE wishes to transmit data but no SR sends resources, then The random access sequence code may be sent to the base station; or, if the UE wishes to transmit data and has an SR transmission resource, the SR may be sent to the base station. After the UE sends the service request to the base station, the information about the QoS level of the first service and/or the type of the resource required by the first service is reported to the base station. For example, after receiving the service request of the UE, the base station may initiate a process of establishing an RRC connection, where the UE may carry the QoS level of the first service and/or the first service required in the RRC connection setup complete message sent to the base station. Resource Type. After the RRC connection is established, the base station determines, according to the QoS level of the first service initiated by the UE and/or the resource type required by the first service, from the set DTX configuration that uses the at least one DTX parameter set for discontinuous transmission. A DTX configuration for discontinuous transmission using a third DTX parameter set, compliant with a QoS level of the first service and/or a resource type required for the first service, and a DTX configuration for discontinuous transmission using the third DTX parameter set Notify the UE in the cell. After the base station determines the active state time of the third DTX period according to the DTX configuration that performs the discontinuous transmission by using the third DTX parameter set, and receives the uplink data sent by the UE in the active state time of the third DTX period. . Optionally, the base station may send, by using an RRC dedicated signaling or a paging message or a broadcast message, a DTX configuration that uses the third DTX parameter set for discontinuous transmission to the UE.

The method further includes: if the DTX configuration uses non-continuous transmissions other than the third DTX parameter set, switching the DTX configuration to non-continuous transmission by using the third DTX parameter set to The third DTX parameter set performs discontinuous transmission.

In this implementation manner, the base station may change the DTX configuration in real time according to the QoS level of the service requested by the UE and/or the required resource type, etc., to meet the service requirement of the UE; and each time the DTX configuration is changed, the base station will be new. The DTX configuration information is used to notify the UE that initiated the service or other UEs in the cell through the RRC dedicated signaling or the paging message or the broadcast message, so that the behavior between the UE and the base station is achieved in the same optional implementation manner, if there is more in the same period. The UEs can send a service request to the base station at the same time, or a single UE sends multiple service requests to the base station, or multiple UEs send multiple service requests to the base station, and the QoS levels of the requested multiple services are different, the base station can configure the DTX. Switching to the DTX parameter set that best meets the QoS requirement in the DTX parameter set corresponding to multiple services for discontinuous transmission, for example, the active state may be selected for the longest duration and inactive in several DTX parameter sets corresponding to several services. The DTX parameter set with the shortest duration. That is to say, the first service may be multiple. Based on this, step 701 is specifically: receiving, by the UE, requesting to initiate at least A business request for a first business. An embodiment of the step 702 includes: performing discontinuous transmission from the set using at least one DTX parameter set according to the QoS level of the at least one first service and/or the resource type required by the at least one first service In the DTX configuration, determining at least one DTX configuration that uses the fourth DTX parameter set for discontinuous transmission corresponding to the QoS level of the at least one first service and/or the resource type required by the at least one first service; In the DTX configuration in which the at least one fourth DTX parameter set is used for discontinuous transmission, determining that the active state time of the DTX cycle is the longest, and the inactive state time of the DTX cycle is the shortest, using the fourth DTX parameter set for discontinuous transmission. The DTX configuration is used as the DTX configuration for discontinuous transmission using the third DTX parameter set. .

In this embodiment, at least one DTX parameter set is set for the quality of service level and/or the required resource type of different services, and after receiving the service request sent by the UE, receiving the service quality of the service requested by the UE. a level and/or a required resource type, and then determining from a set DTX configuration for discontinuous transmission using at least one DTX parameter set, corresponding to a quality of service level and/or a required resource type of the service requested by the UE The DTX configuration of the discontinuous transmission is performed by using the third DTX parameter set, so that the base station can better adjust the time proportion of the active state and the inactive state according to the different service requirements of the UE, so that the UE can access the cell to obtain the service in time. The delay of the UE accessing or performing data transmission is alleviated, and the problem that the base station performs a relatively long period of DTX and cannot meet the QoS requirement of the UE is solved.

In this embodiment, in the embodiment shown in FIG. 7, the base station can set a timer for timing the active state of the DTX cycle. When the timer expires, the base station enters an inactive state. Optionally, the base station may extend the time in the active state by using a timer. For example, if the base station receives the service request of the UE during the active state, the base station may be restarted by the restart timer to restart the active state. The timer expires and then enters the inactive state.

FIG. 8 is a flowchart of another data sending method according to an embodiment of the present invention. As shown in FIG. 8, the method includes:

Step 801: Send a service request for requesting to initiate a first service to a base station, and send a QoS level of the first service and/or a resource type required by the first service to the base station.

Step 802: Receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a third DTX parameter set, where the DTX configuration that uses the third DTX parameter set to perform discontinuous transmission is the QoS of the base station according to the first service. Level and/or required resource type of the first service, from settings A DTX configuration corresponding to a QoS level of the first service and/or a resource type required by the first service determined in a DTX configuration of discontinuous transmission using at least one discontinuous transmit DTX parameter set.

Step 803: Determine, according to the DTX configuration that uses the third DTX parameter set for discontinuous transmission, an active state time of the third DTX cycle.

Step 804: Send uplink data to the base station in an active state time of the third DTX period.

In an optional implementation manner, the sending, by the base station, the QoS level of the first service and/or the resource type required by the first service, includes: sending an RRC connection setup complete message to the base station, where the RRC The connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

In an optional implementation manner, the receiving, by the base station, the DTX configuration that uses the third DTX parameter set to perform the discontinuous transmission includes: receiving an RRC dedicated signaling or a paging message or a broadcast message sent by the base station, where The RRC dedicated signaling or paging message or broadcast message includes the DTX configuration for discontinuous transmission using the third DTX parameter set.

This embodiment is a description from the perspective of the UE, and is compatible with the data receiving method provided in the embodiment shown in FIG. 7. The detailed description is not described herein again.

Herein, the service request sent by the UE includes an SR or a random access request.

In this embodiment, at least one DTX parameter set is set for a service quality level and/or a required resource type of different services, and after receiving the service request sent by the UE, the base station receives the service requested by the UE for performing the service. a quality level and/or a required resource type, and then from a set DTX configuration for discontinuous transmission using at least one DTX parameter set, determining a quality of service level and/or a required resource type for the service requested by the UE The DTX configuration of the discontinuous transmission using the third DTX parameter set enables the base station to better adjust the time ratio between the active state and the inactive state according to different service requirements of the UE, and performs the third DTX parameter set. The DTX configuration of the continuous transmission is notified to the UE, so that the UE can access the cell to obtain the service in time, which reduces the delay of the UE accessing or performing the data transmission, and solves the problem that the UE cannot perform the UE due to the relatively long period of DTX. The problem of QoS requirements.

FIG. 9 is a flowchart of still another data receiving method according to an embodiment of the present invention. As shown in FIG. 9, the method includes: Step 990011, and receive and send UUEE sent and sent business services request request. .

Step 990022, according to the business service request according to the description, the root state state is switched from the DDTTXX state state state to the continuous continuous emission state. .

Step 990033, sending, to the UUEE, the transmitting state state of the continuous continuous transmitting state state after the switching is performed. . . In step 55, step 990044, the number of uplink lines sent and received by the UUEE is received and received in the continuous continuous transmission state state after the switching is performed. Data. .

In the optional implementation manner, in step 990044, after the step 990044, the package further includes: determining that the uplink data of the UUEE is sent and sent according to the data. After the completion of the completion, the state of the emitted radiation state state will be switched from the continuous continuous emission state state to the DDTTXX state state state, and the switch will be switched. The transmitting state of the DDTTXX state state is sent to the UUEE. . The process of determining whether the upper uplink data of the UUEE is determined to be sent or not is completed. 1100 After the completion of the delivery process, reference is made to the embodiment shown in FIG. The description of the examples will not be described again here. .

In an optional implementation manner, the method of the method further includes: in the state of being DDTTXX in the state of being emitted When the state-cut switching is changed to the continuous continuous emission state state, when the start-up is started, when the beam ends at the time of counting, the state of the emitted-fire state will be Transmitting from the continuous continuous emission state transition to the DDTTXX state state state, and transmitting and transmitting the DDTTXX state state of the DDTTXX state state after switching It is sent to the UUEE described. .

1155 can be selected in a step by step, if, if it is before the end of the knot at the time of counting, the base station receives and receives the business services sent by other other UUEEs. Please request, and then re-open the new time to start counting. . For example, the base station may be able to start a timed timer ((may be similar to the DDRRXX-like iinnaaccttiivviittyy ttiimmeerr)), for the pre-set time When the time is counted, if the fruit base station receives the business service request sent by other UUEEs during the timing period of the fixed timer, then Then, the timing device is restarted to extend the time period in which the long base station is in continuous continuous emission state state; After the end of the timing, (or or after the timeout), the base station station has not received the business services of other UUEEs.

2200 Please request, and then re-enter the DDTTXX state state, in order to enter the provincial power state state. .

Optionally, the base base station station may pass the RRRRCC special-purpose signaling or the paging-calling message or the wide-broadcast message, and the switch will be switched. Sending and transmitting the state of the continuation of the continuation of the emission state state and the morphing state of the DDTTXX state state after the switching is sent to Give the described UUEE. .

In the example of the implementation of the present embodiment, under the condition that the UUEE has a demand for business services, the base station will transmit the state of the launch state from the DDTTXX state state 2255. The change is changed to continuous continuous transmission of the state of the launching state, which may enable the UUEE and the timely access to the small cell area to obtain the service, and the UUEE access is reduced. Or the time delay of the data transmission and transmission of the line number data is transmitted, and the solution is determined by the DDTTXX which is performed by the base station station and performs a longer long cycle period than the base station. There is no problem that the QQooSS of UUEE needs to satisfy the problem, and the transmission or transmission of the above-mentioned data on the UUEE is guaranteed. .

FIG. 1100 is a flow chart showing still another method for transmitting data according to the embodiment of the present invention. . As shown in FIG. 1100, the method package includes: Step 1002: Receive a transmission status of the continuous transmission that is sent by the base station according to the service request, and the transmission status before the base station handover is a discontinuous transmission DTX status.

Step 1003: Determine, according to the transmission status of the continuous transmission after the base station is switched, the time for transmitting the uplink data and/or switch the transmission status to the transmission status of the continuous transmission.

It is to be noted that the time for transmitting the uplink data is determined according to the transmission state of the continuous transmission after the handover of the base station is applicable to the scenario in which the UE adopts the DRX. And switching the transmission state to the transmission state of the continuous transmission according to the transmission state of the continuous transmission after the base station is switched is applicable to any scenario.

Step 1004: Send uplink data to the base station according to the determined time for transmitting uplink data and/or in a transmitting state of continuous transmission.

In an optional implementation manner, the method further includes: receiving, after the handover sent by the base station

The transmit state of the DTX state.

In this embodiment, when the UE has a service demand, the base station sends the local transmission status by

The DTX state is changed to the continuous transmission state, and the changed transmission state is notified to the UE, and the UE can access the cell to obtain the service in time, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period. The DTX brings the problem that the QoS requirements of the UE cannot be met, thereby ensuring the transmission or access of the above data of the UE.

FIG. 11 is a schematic structural diagram of a base station according to an embodiment of the present invention. As shown in FIG. 11, the base station includes: a receiving module 110, a switching module 111, a sending module 112, and a determining module 113.

The receiving module 110 is configured to receive a service request sent by the UE.

The switching module 111 is connected to the receiving module 110, and is configured to switch the DTX configuration from the discontinuous transmission by using the first DTX parameter set to the non-continuous transmission by using the second DTX parameter set according to the service request sent by the UE received by the receiving module 110. Continuously transmitting, an active state time of a first DTX cycle in the first DTX parameter set is less than an active state time of a second DTX cycle in the second DTX parameter set, or a first DTX cycle in the first DTX parameter set The ratio of the active state time in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle.

The sending module 112 is connected to the switching module 1 11 and configured to send, to the UE, the DTX configuration that uses the second DTX parameter set to perform discontinuous transmission after the switching module 111 switches the DTX configuration. The determining module 113 is connected to the switching module 111, and is configured to determine an active state time of the second DTX cycle according to the DTX configuration that is used after the switching of the switching module 111 to perform discontinuous transmission by using the second DTX parameter set.

The receiving module 110 is connected to the determining module 1 13 and configured to receive the uplink data sent by the UE in an active state time of the second DTX period determined by the determining module 113.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In an example, the active state time of the first DTX cycle in the first DTX parameter set may be equal to the active state time of the second DTX cycle in the second DTX parameter set, and the first DTX parameter set A DTX period is greater than a second DTX period in the second DTX parameter set.

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. In an optional implementation, the switching module 11 is further configured to determine that the uplink data of the UE is sent, and switch the DTX configuration by using the second DTX parameter set to perform the discontinuous transmission. A DTX parameter set performs discontinuous transmission. Correspondingly, the sending module 112 is further configured to: after the switching module 111 switches the DTX configuration that uses the second DTX parameter set for discontinuous transmission, the DTX configuration that uses the first DTX parameter set to perform discontinuous transmission. Sent to the UE.

Optionally, the sending module 112 is specifically configured to send, by using the first RRC dedicated signaling or the first paging message or the first broadcast message, the DTX configuration that is discontinuously transmitted by using the second DTX parameter set to the UE.

Optionally, the sending module 112 is specifically configured to send, by using the second RRC dedicated signaling or the second paging message or the second broadcast message, the DTX configuration that is discontinuously transmitted by using the first DTX parameter set to the UE. .

Optionally, the base station further includes: a connection establishment module.

a connection establishing module, configured to establish with the UE according to the service request received by the receiving module 110 RRC connection. Based on this, the receiving module 1 is specifically configured to receive the uplink data sent by the UE in an active state time of the second DTX period by using the RRC connection established by the connection establishing module.

In this embodiment, the service request sent by the UE includes but is not limited to: an SR or a random access request.

The function modules of the base station provided in this embodiment may be used to perform the process of the method embodiment shown in FIG. 1 or FIG. 4 or FIG. 5. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The base station provided in this embodiment is configured to set two DTX parameter sets, where the active state time of the DTX cycle included in the first parameter set is shorter, and the active state time of the DTX cycle included in the second parameter set is longer. When the UE initiates the service, the base station performs DTX by using the parameters of the first parameter set, so that the base station can save power; after receiving the service request of the UE, by changing the DTX configuration to the configuration of the second parameter set, the present embodiment provides The base station can extend the time in the active state when the UE has the service requirement, and reduce the time in the inactive state, so that the UE can access the cell to obtain the service in time, thereby reducing the delay of the UE accessing or performing data transmission, and solving the problem. Since the base station performs a relatively long period of DTX, the problem that the UE's QoS requirements cannot be met is brought about.

FIG. 12 is a schematic structural diagram of another base station according to an embodiment of the present invention. As shown in FIG. 12, the base station includes: a processor 121, a transmitter 122, and a receiver 123.

The receiver 123 is configured to receive a service request sent by the UE.

The processor 121 is configured to switch the DTX configuration from the discontinuous transmission by using the first DTX parameter set to the discontinuous transmission by using the second DTX parameter set according to the service request sent by the UE received by the receiver 123, where the first DTX is used. The active state time of the first DTX cycle in the parameter set is less than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is in the first DTX The ratio in the period is less than the ratio of the active state time of the second DTX period in the second DTX parameter set in the second DTX period.

The active state time of the first DTX cycle in the first DTX parameter set is in the first DTX cycle The ratio is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. The processor 121 may be a central processing unit (CPU), or an application specific integrated circuit (ASIC), or one or more configured to implement the embodiments of the present invention. integrated circuit.

The transmitter 122 is configured to send, to the UE, the DTX configuration that is used by the processor 121 to perform discontinuous transmission using the second DTX parameter set after the DTX configuration is switched.

The processor 121 is further configured to determine an active state time of the second DTX cycle according to the DTX configuration that performs discontinuous transmission by using the second DTX parameter set.

The receiver 123 is further configured to receive uplink data sent by the UE in an active state time of the second DTX period determined by the processor 121.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In an optional implementation, the processor 121 is further configured to determine that the uplink data of the UE is sent, and switch the DTX configuration by using the second DTX parameter set to use the first The DTX parameter set performs discontinuous transmission. Correspondingly, the transmitter 122 is further configured to: after the processor 121 switches the DTX configuration that uses the second DTX parameter set for discontinuous transmission, the DTX configuration that uses the first DTX parameter set for discontinuous transmission. Sent to the UE.

Optionally, the transmitter 122 is specifically configured to send, by using the first RRC dedicated signaling or the first paging message or the first broadcast message, the DTX configuration that is discontinuously transmitted by using the second DTX parameter set to the UE. .

Optionally, the transmitter 122 is specifically configured to send, by using the second RRC dedicated signaling or the second paging message or the second broadcast message, the DTX configuration that is discontinuously transmitted by using the first DTX parameter set to the UE. .

Optionally, the processor 121 is further configured to establish an RRC connection with the UE according to the service request received by the receiver 123. Based on this, the receiver 123 is specifically configured to receive, by using the RRC connection established by the processor 121, uplink data sent by the UE in an active state time of the second DTX period.

In this embodiment, the service request sent by the UE includes but is not limited to: an SR or a random access request. Further, the base station may further include: a memory.

Memory, used to store programs. In particular, the program can include program code, the program code including computer operating instructions. Based on this, the processor 121 can specifically implement the above functions by executing the program, but is not limited thereto.

The memory can include high speed RAM memory or nonvolatile memory

(non-volatile memory), such as at least one disk storage.

Optionally, in a specific implementation, the processor 121, the transmitter 122, and the receiver 123 can be connected to each other through a bus and complete communication with each other. The bus may be an Industry Standard Architecture (ISA) bus, a Peripheral Component (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus. Wait. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is shown in Figure 12, but it does not mean that there is only one bus or one type of bus.

Optionally, in a specific implementation, the processor 121, the transmitter 122, and the receiver 123 can perform the same communication through the internal interface.

The base station provided in this embodiment can be used to perform the process of the method embodiment shown in FIG. 1 or FIG. 4 or FIG. 5, and the specific working principle is not described here. For details, refer to the description of the method embodiment.

The base station provided in this embodiment is configured to set two DTX parameter sets, where the active state time of the DTX cycle included in the first parameter set is shorter, and the active state time of the DTX cycle included in the second parameter set is longer. When the UE initiates the service, the base station performs the DTX by using the parameters of the first parameter set, so that the base station can save the power; after receiving the service request of the UE, the DTX configuration is switched to the configuration of the second parameter set, so that the embodiment provides The base station can extend the time in the active state when the UE has the service requirement, and reduce the time in the inactive state, so that the UE can access the cell to obtain the service in time, thereby reducing the delay of the UE accessing or performing data transmission, and solving the problem. Since the base station performs a relatively long period of DTX, the problem that the UE's QoS requirements cannot be met is brought about.

FIG. 13 is a schematic structural diagram of a UE according to an embodiment of the present invention. As shown in FIG. 13, the UE includes: a sending module 131, a receiving module 132, and a determining module 133.

The sending module 131 is configured to send a service request to the base station.

The receiving module 132 is configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a second DTX parameter set, where the second discontinuous transmit DTX parameter set is used for discontinuous transmission. The transmitted DTX is configured as a DTX configuration used by the base station to switch from a DTX configuration that uses a first DTX parameter set for discontinuous transmission according to a service request sent by the sending module, and a first DTX period in the first DTX parameter set. The active state time is less than the active state time of the second DTX cycle in the second DTX parameter set, or the active state time of the first DTX cycle in the first DTX parameter set is less than the ratio in the first DTX cycle. The ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle.

The determining module 133 is configured to determine an active state time of the second DTX period according to the DTX configuration received by the receiving module 132 for non-continuous transmission by using the second DTX parameter set.

The sending module 131 is further configured to send uplink data to the base station within an active state time of the second DTX period determined by the determining module 133.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In an optional implementation, the receiving module 132 is further configured to: after the sending module 131 sends uplink data to the base station in an active state of the second DTX period, receive the first DTX parameter set sent by the base station. DTX configuration for discontinuous transmission.

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. Optionally, the receiving module 132 is specifically configured to receive the first RRC dedicated signaling or the first paging message or the first broadcast message sent by the base station, where the first RRC dedicated signaling or the first paging message or the first A broadcast message includes a DTX configuration for non-continuous transmission using a second set of DTX parameters.

Optionally, the receiving module 132 is specifically configured to receive the second RRC dedicated signaling or the second paging message or the second broadcast message sent by the base station, where the second RRC dedicated signaling or the second paging message or the first The second broadcast message includes the DTX configuration for non-continuous transmission using the first DTX parameter set. In this embodiment, the service request sent by the sending module 131 includes but is not limited to: an SR or a random access request.

The function modules of the UE provided in this embodiment can be used to perform the process of the data sending method shown in FIG. 6. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The UE provided in this embodiment cooperates with the base station provided by the foregoing embodiment to support the base station to set two DTX parameter sets, so that when the UE has a service request, the base station may adopt a second DTX parameter set with a longer active state time, and The switched DTX configuration is provided to the UE, and the UE in this embodiment receives the switched DTX configuration provided by the base station, and synchronizes with the base station, and sends the data to the base station during the active state of the second DTX period of the second DTX parameter set. The uplink data can access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

FIG. 14 is a schematic structural diagram of another UE according to an embodiment of the present invention. As shown in FIG. 14, the UE includes: a transmitter 141, a receiver 142, and a processor 143.

The transmitter 141 is configured to send a service request to the base station.

The receiver 142 is configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a second DTX parameter set, where the DTX configured to perform discontinuous transmission by using the second discontinuous transmit DTX parameter set is the base station. And the DTX configuration used after the DTX configuration switching of the discontinuous transmission by using the first DTX parameter set is performed according to the service request sent by the sending module, and the active state time of the first DTX period in the first DTX parameter set is smaller than the first The active state time of the second DTX cycle in the two DTX parameter sets, or the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the second in the second DTX parameter set The ratio of the active state time of the DTX cycle in the second DTX cycle.

The processor 143 is configured to determine an active state time of the second DTX cycle according to a DTX configuration received by the receiver and configured to perform non-continuous transmission by using a second DTX parameter set.

The transmitter 141 is further configured to transmit uplink data to the base station within an active state time of the second DTX period determined by the processor 143.

Further optionally, the first DTX period may be greater than or equal to the second DTX period. In an example, the active state time of the first DTX cycle in the first DTX parameter set may be And an active state time equal to a second DTX period in the second DTX parameter set, and a first DTX period in the first DTX parameter set is greater than a second DTX period in the second DTX parameter set.

The ratio of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the ratio of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle. In an optional implementation, the receiver 142 is further configured to perform DTX of the discontinuous transmission by using the first DTX parameter set after the transmitter 141 sends the uplink data to the base station in the active state time of the second DTX period. Configuration.

Optionally, the receiver 142 is specifically configured to receive the first RRC dedicated signaling or the first paging message or the first broadcast message sent by the base station, where the first RRC dedicated signaling or the first paging message or the first A broadcast message includes a DTX configuration for non-continuous transmission using a second set of DTX parameters.

Optionally, the receiver 142 is specifically configured to receive the second RRC dedicated signaling or the second paging message or the second broadcast message sent by the base station, where the second RRC dedicated signaling or the second paging message or the first The second broadcast message includes the DTX configuration for non-continuous transmission using the first DTX parameter set.

In this embodiment, the service request sent by the transmitter 141 includes but is not limited to: an SR or a random access request.

Further, the UE further includes: a memory.

Memory, used to store programs. In particular, the program can include program code, the program code including computer operating instructions.

The processor 143 can be used to execute a program of memory storage for implementing control logic or the like of the UE.

The memory may include a high speed RAM memory, and may also include a non-volatile memory, such as at least one disk memory.

Processor 143 can be a CPU, or a particular ASIC, or one or more integrated circuits configured to implement embodiments of the present invention.

Optionally, in a specific implementation, the transmitter 141, the receiver 142, and the processor 143 may be connected to each other through a bus and complete communication with each other. The bus can be an ISA bus, a PCI bus, or an EISA bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For the sake of In the representation, only one thick line is shown in Fig. 14, but it does not mean that there is only one bus or one type of bus.

Optionally, in a specific implementation, the transmitter 141, the receiver 142, and the processor 143 can complete the same communication through the internal interface.

Further optionally, the UE may further include an input unit, a display unit, a power module, an audio circuit, and the like in addition to the transmitter 141, the receiver 142, and the processor 143. The input unit may be a touch panel or other input device, and the display unit may be a display panel or the like.

The UE provided in this embodiment can be used to perform the process of the data sending method shown in FIG. 6. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The UE provided in this embodiment cooperates with the base station provided by the foregoing embodiment, and supports the base station to set two DTX parameter sets, so that when the UE has a service request, the base station may adopt a second DTX parameter set with a longer active state time, and The switched DTX configuration is provided to the UE, and the UE in this embodiment receives the switched DTX configuration provided by the base station, and synchronizes with the base station, and sends the data to the base station during the active state of the second DTX period of the second DTX parameter set. The uplink data can be used to access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

FIG. 15 is a schematic structural diagram of still another base station according to an embodiment of the present invention. As shown in FIG. 15, the base station includes: a receiving module 151, a determining module 152, and a sending module 153.

The receiving module 151 is configured to receive a service request sent by the UE for requesting to initiate the first service, and receive a QoS level of the first service and/or a resource type required by the first service sent by the UE.

The determining module 152 is connected to the receiving module 151, and configured to perform discontinuous operation from the set using at least one DTX parameter set according to the QoS level of the first service and/or the resource type required by the first service received by the receiving module 151. In the transmitted DTX configuration, a DTX configuration that uses the third DTX parameter set for discontinuous transmission corresponding to the QoS level of the first service and/or the resource type required by the first service is determined.

Optionally, the determining module 152 is further configured to: when the DTX configuration uses the third DTX parameter set to perform discontinuous transmission, switch the DTX configuration by using a non-continuous transmission that is not the third DTX parameter set to The discontinuous transmission is performed using the third DTX parameter set.

Optionally, the at least one DTX parameter set respectively corresponds to a different parameter combination, where the parameter The combination includes at least one of a QoS class and a resource type.

The sending module 153 is connected to the determining module 152, and configured to send, to the UE, the DTX configuration determined by the determining module 152 to perform discontinuous transmission by using the third DTX parameter set.

The determining module 152 is further configured to determine an active state time of the third DTX cycle according to the DTX configuration for performing discontinuous transmission by using the third DTX parameter set.

The receiving module 151 is further configured to receive the uplink data sent by the UE in an active state time of the third DTX period determined by the determining module 152.

Optionally, the receiving module 151 is specifically configured to receive an RRC connection setup complete message sent by the UE, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

Optionally, the sending module 154 is specifically configured to send, by using an RRC dedicated signaling or a paging message or a broadcast message, the DTX configuration that uses the third DTX parameter set for discontinuous transmission to the UE.

In an optional implementation manner, the first service is multiple. Based on this, the receiving module 151 is configured to receive a service request sent by the UE to request to initiate at least one first service. The determining module 152 is specifically configured to perform discontinuous transmission from the set using at least one discontinuous transmit DTX parameter set according to the QoS level of the at least one first service and/or the resource type required by the at least one first service. Determining, in the DTX configuration, at least one DTX configuration that uses the fourth DTX parameter set for discontinuous transmission corresponding to the QoS level of the at least one first service and/or the resource type required by the at least one first service, In the DTX configuration in which the at least one fourth DTX parameter set is used for discontinuous transmission, determining that the active state time of the DTX cycle is the longest, and the inactive state time of the DTX cycle is the shortest, using the fourth DTX parameter set for discontinuous transmission. The DTX configuration is used as the DTX configuration for discontinuous transmission using the third DTX parameter set.

In this embodiment, the service request received by the receiving module 151 includes but is not limited to: an SR or a random access request.

The function modules of the base station provided in this embodiment can be used to perform the process of the data receiving method shown in FIG. 7. The specific working principle is not described here. For details, refer to the description of the method embodiments.

The base station provided in this embodiment sets at least one DTX parameter set for the service quality level and/or the required resource type of different services, and after receiving the service request sent by the UE, the service performed according to the request sent by the UE Quality level and/or required resource type, then determining the service requested by the UE from the DTX configuration for discontinuous transmission using at least one DTX parameter set The DTX configuration for the discontinuous transmission using the third DTX parameter set corresponding to the quality of service level and/or the required resource type, so that the base station can better adjust the time in the active state and the inactive state according to different service requirements of the UE. The ratio can enable the UE to access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

FIG. 16 is a schematic structural diagram of still another base station according to an embodiment of the present invention. As shown in FIG. 16, the base station includes: a receiver 161, a processor 162, and a transmitter 163.

The receiver 161 is configured to receive a service request sent by the UE for requesting to initiate the first service, and receive a QoS level of the first service and/or a resource type required by the first service sent by the UE.

The processor 162 is configured to: according to the QoS level of the first service received by the receiver 161 and/or the resource type required by the first service, from the set DTX configuration that performs discontinuous transmission by using at least one DTX parameter set, Determining a DTX configuration for discontinuous transmission using the third DTX parameter set corresponding to the QoS level of the first service and/or the resource type required by the first service.

Optionally, the processor 162 is further configured to: when the DTX configuration uses the third DTX parameter set for discontinuous transmission, switch the DTX configuration by using a non-continuous transmission that is not the third DTX parameter set to The discontinuous transmission is performed using the third DTX parameter set.

Optionally, the at least one DTX parameter set respectively corresponds to different parameter combinations, and the parameter combination includes at least one of a QoS class and a resource type.

The transmitter 163 is configured to send, to the UE, a DTX configuration determined by the processor 162 to perform discontinuous transmission by using a third DTX parameter set.

The processor 162 is further configured to determine an active state time of the third DTX cycle according to the DTX configuration for performing discontinuous transmission by using the third DTX parameter set.

The receiver 161 is further configured to receive the uplink data sent by the UE during an active state of the third DTX period determined by the processor 162.

Optionally, the receiver 161 is specifically configured to receive an RRC connection setup complete message sent by the UE, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

Optionally, the transmitter 163 is specifically configured to send, by using an RRC dedicated signaling or a paging message or a broadcast message, the DTX configuration that uses the third DTX parameter set for discontinuous transmission to the UE.

In an optional implementation manner, the first service is multiple. Based on this, the receiver 161 is specific And configured to receive a service request sent by the UE to request to initiate at least one first service. The processor 162 is specifically configured to perform, according to the QoS level of the at least one first service and/or the resource type required by the at least one first service, from the set of discontinuous transmission by using at least one discontinuous transmit DTX parameter set. Determining, in the DTX configuration, at least one DTX configuration that uses the fourth DTX parameter set for discontinuous transmission corresponding to the QoS level of the at least one first service and/or the resource type required by the at least one first service, In the DTX configuration in which the at least one fourth DTX parameter set is used for discontinuous transmission, determining that the active state time of the DTX cycle is the longest, and the inactive state time of the DTX cycle is the shortest, using the fourth DTX parameter set for discontinuous transmission. The DTX configuration is used as the DTX configuration for discontinuous transmission using the third DTX parameter set.

In this embodiment, the service request received by the receiver 161 includes but is not limited to: an SR or a random access request.

Further, the base station further includes: a memory.

Memory, used to store programs. In particular, the program can include program code, the program code including computer operating instructions. Based on this, the processor 162 can implement the above functions by executing a program stored in the memory, but is not limited thereto.

Processor 162 can be a CPU, or a specific ASIC, or one or more integrated circuits configured to implement embodiments of the present invention.

Optionally, in a specific implementation, the receiver 161, the processor 162, and the transmitter 163 can be connected to each other through a bus and complete communication with each other. The bus can be an ISA bus, a PCI bus or an EISA bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is shown in Figure 16, but it does not mean that there is only one bus or one type of bus.

Optionally, in a specific implementation, the receiver 161, the processor 162, and the transmitter 163 can complete the same communication through the internal interface.

The base station provided in this embodiment can be used to perform the process of the data receiving method shown in FIG. 7. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The base station provided in this embodiment sets at least one DTX parameter set for the service quality level and/or the required resource type of different services, and after receiving the service request sent by the UE, according to the UE The quality of service level and/or the type of resource required for the service requested to be sent, and then from the DTX configuration for discontinuous transmission using at least one DTX parameter set, determining the quality of service level of the service requested by the UE and/or The third DTX parameter set corresponding to the required resource type performs the DTX configuration of the discontinuous transmission, so that the base station can better adjust the time proportion of the active state and the inactive state according to different service requirements of the UE, so that the UE can be timely The access cell obtains the service, which reduces the delay of the UE accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

FIG. 17 is a schematic structural diagram of still another UE according to an embodiment of the present invention. As shown in FIG. 17, the UE includes: a sending module 171, a receiving module 172, and a determining module 173.

The sending module 171 is configured to send, to the base station, a service request for requesting to initiate the first service, and send, to the base station, a QoS level of the first service and/or a resource type required by the first service.

The receiving module 172 is configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a third DTX parameter set, where the DTX configuration that uses the third DTX parameter set to perform discontinuous transmission is that the base station is configured according to the first a QoS level of the service and/or a required resource type of the first service, a QoS level and/or a QoS level of the first service determined from a set DTX configuration for discontinuous transmission using at least one DTX parameter set The DTX configuration corresponding to the resource type required by the first service.

The determining module 173 is connected to the receiving module 172, and is configured to determine an active state time of the third DTX cycle according to the DTX configuration received by the receiving module 172 for discontinuous transmission by using the third DTX parameter set.

The transmitting module 171 is further configured to send uplink data to the base station within an active state time of the third DTX period determined by the determining module 173.

Optionally, the sending module 171 is specifically configured to send an RRC connection setup complete message to the base station, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

Optionally, the receiving module 172 is specifically configured to receive an RRC dedicated signaling or a paging message or a broadcast message sent by the base station, where the RRC dedicated signaling or paging message or the broadcast message includes the third DTX parameter set. DTX distribution for discontinuous transmission.

In this embodiment, the service request sent by the sending module 171 includes but is not limited to: an SR or a random access request. The function modules of the UE provided in this embodiment can be used to perform the process of the data sending method shown in FIG. 8. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The UE provided in this embodiment cooperates with the base station provided by the foregoing embodiment, and supports the base station to set at least one DTX parameter set for the service quality level and/or the required resource type of different services, and the supporting base station sends the UE according to the embodiment. The service request selects a suitable DTX parameter set for the requested service, and the base station provides the switched DTX configuration to the UE. The UE in this embodiment is based on the DTX configuration provided by the base station, and the active state time of the DTX cycle in the corresponding DTX parameter set. The inbound base station sends the uplink data, and can access the cell to obtain the service in time, which reduces the delay of accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE.

FIG. 18 is a schematic structural diagram of still another UE according to an embodiment of the present invention. As shown in FIG. 18, the UE includes: a transmitter 181, a receiver 182, and a processor 183.

The transmitter 181 is configured to send, to the base station, a service request for requesting to initiate the first service, and send, to the base station, a QoS level of the first service and/or a resource type required by the first service.

The receiver 182 is configured to receive a DTX configuration that is sent by the base station to perform discontinuous transmission by using a third DTX parameter set, where the DTX configuration that uses the third DTX parameter set to perform discontinuous transmission is that the base station is configured according to the first a QoS level of the service and/or a required resource type of the first service, a QoS level and/or a QoS level of the first service determined from a set DTX configuration for discontinuous transmission using at least one DTX parameter set The DTX configuration corresponding to the resource type required by the first service.

The processor 183 is configured to determine an active state time of the third DTX cycle according to the DTX configuration received by the receiver 182 for non-continuous transmission by using the third DTX parameter set.

The transmitter 181 is further configured to send uplink data to the base station within an active state time of the third DTX period determined by the processor 183.

Optionally, the transmitter 181 is specifically configured to send an RRC connection setup complete message to the base station, where the RRC connection setup complete message includes a QoS level of the first service and/or a resource type required by the first service.

Optionally, the receiver 182 is specifically configured to receive an RRC dedicated signaling or a paging message or a broadcast message sent by the base station, where the RRC dedicated signaling or the paging message or the broadcast message includes the third DTX parameter set. DTX configuration for discontinuous transmission.

In this embodiment, the service request sent by the transmitter 181 includes but is not limited to: SR or Machine access request.

Further, the UE further includes: a memory.

The processor 183 can be used to execute a program of memory storage for implementing control logic or the like of the UE.

The memory may include a high speed RAM memory, and may also include a non-volatile memory such as at least one disk memory.

Processor 183 can be a CPU, or a particular ASIC, or one or more integrated circuits configured to implement embodiments of the present invention.

Optionally, in a specific implementation, the transmitter 181, the receiver 182, and the processor 183 can be connected to each other through a bus and complete communication with each other. The bus can be an ISA bus, a PCI bus or an EISA bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is shown in Figure 18, but it does not mean that there is only one bus or one type of bus.

Optionally, in a specific implementation, the transmitter 181, the receiver 182, and the processor 183 can complete the same communication through the internal interface.

Further optionally, the UE may further include an input unit, a display unit, a power module, an audio circuit, and the like in addition to the transmitter 181, the receiver 182, the memory, and the processor 183. The input unit may be a touch panel or other input device, and the display unit may be a display panel or the like.

The UE provided in this embodiment can be used to perform the process of the data sending method shown in FIG. 8. The specific working principle is not described here. For details, refer to the description of the method embodiment.

The UE provided in this embodiment cooperates with the base station provided by the foregoing embodiment, and supports the base station to set at least one DTX parameter set for the service quality level and/or the required resource type of different services, and the supporting base station sends the UE according to the embodiment. The service request selects a suitable DTX parameter set for the requested service, and the base station provides the switched DTX configuration to the UE. The UE in this embodiment is based on the DTX configuration provided by the base station, and the active state time of the DTX cycle in the corresponding DTX parameter set. The inbound base station sends the uplink data, and can access the cell to obtain the service in time, which reduces the delay of accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX, which cannot meet the QoS requirement of the UE. question.

FIG. 19 is a schematic structural diagram of still another base station according to an embodiment of the present invention. As shown in FIG. 19, the base station includes: a switching module 191, a sending module 192, and a receiving module 193.

The receiving module 193 is configured to receive a service request sent by the UE.

The switching module 191 is configured to switch the transmission state from the DTX state to the continuous transmission state according to the service request received by the receiving module 193.

The sending module 192 is connected to the switching module 191, and is configured to send, to the UE, the transmitting status of the continuous transmitting state after the switching module 191 is switched.

The receiving module 193 is further configured to receive the uplink data sent by the UE in a continuous transmission state after the handover of the switching module 191.

In an optional implementation manner, the UE further includes: a determining module. And a determining module, configured to determine that the uplink data of the UE is sent. The switching module 191 is further configured to switch the transmitting state to a DTX state after the determining module determines that the uplink data of the UE is sent. Correspondingly, the sending module 192 is further configured to send, to the UE, a transmit status of the DTX state after the switching module is switched.

In an optional implementation manner, the base station further includes: a timing module.

The timing module is configured to start timing when the switching module 191 switches the transmission state from the DTX state to the continuous transmission state. The switching module 191 is further configured to switch the transmission state from a continuous transmission state to a DTX state at the end of the timing module timing. Correspondingly, the sending module 192 is further configured to send the transmit status of the DTX state after the switching module 191 is switched to the UE.

Further, the timing module is further configured to restart timing when the receiving module 193 receives a service request sent by another UE before the timer ends.

In this embodiment, the service request includes but is not limited to: an SR or a random access request.

The function modules of the base station provided in this embodiment can be used to perform the process of the data receiving method shown in FIG. 9. The specific working principle is not described here. For details, refer to the description of the method embodiments.

The base station provided in this embodiment, when the UE has a service requirement, uses the local transmission status by

The DTX state is switched to the continuous transmission state, which enables the UE to access the cell in time to obtain the service, which reduces the delay of the UE accessing or performing the data transmission, and solves the problem that the base station performs the relatively long period of DTX, which cannot meet the UE. The problem of QoS requirements ensures the transmission or access of the above data of the UE.

FIG. 20 is a schematic structural diagram of still another base station according to an embodiment of the present invention. As shown in FIG. 20, the base station includes: a processor 2001, a transmitter 2002, and a receiver 2003. The receiver 2003 is configured to receive a service request sent by the UE.

The processor 2001 is configured to switch the transmission state from the DTX state to the continuous transmission state according to the service request received by the receiver 2003.

The transmitter 2002 is configured to send, to the UE, a transmission status of the continuous transmission state after the processor 2001 is switched.

The receiver 2003 is further configured to receive uplink data sent by the UE in a continuous transmission state after the processor 2001 is switched.

In an optional implementation, the processor 2001 is further configured to determine that the uplink data of the UE is sent, and switch the transmission state to a DTX state. Correspondingly, the transmitter 2002 is further configured to send the transmission status of the DTX state after the processor 2001 is switched to the UE.

In an optional implementation, the processor 2001 is further configured to start timing when the transmitting state is switched from a DTX state to a continuous transmitting state, and switch the transmitting state from a continuous transmitting state to a DTX state at the end of timing. . The transmitter 2002 is further configured to send, to the UE, a transmit status of the DTX state after the processor 2001 is switched.

Further optionally, the processor 2001 is further configured to resume timing when the receiver 2003 receives a service request sent by another UE before the timer ends.

Further, the base station further includes: a memory.

Memory, used to store programs. In particular, the program can include program code, the program code including computer operating instructions. Based on this, the processor 2001 can implement the above functions by executing a program stored in the memory, but is not limited thereto.

The processor 2001 can be a CPU, or a specific ASIC, or one or more integrated circuits configured to implement embodiments of the present invention.

Optionally, in a specific implementation, the processor 2001, the transmitter 2002, and the receiver 2003 may be connected to each other through a bus and complete communication with each other. The bus can be an ISA bus, a PCI bus, or an EISA bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is shown in Figure 20, but it does not mean that there is only one bus or one type of bus. Optionally, in a specific implementation, the processor 2001, the transmitter 2002, and the receiver 2003 can complete the same communication through an internal interface.

The base station provided in this embodiment can be used to perform the process of the data receiving method shown in FIG. 9. The specific working principle is not described here. For details, refer to the description of the method embodiment.

FIG. 21 is a schematic structural diagram of still another UE according to an embodiment of the present invention. As shown in FIG. 21, the UE includes: a sending module 2101, a receiving module 2102, and a determining module 2103.

The sending module 2101 is configured to send a service request to the base station.

The receiving module 2102 is configured to receive, by the base station, a transmission status of the continuous transmission that is changed by the base station according to the service request, where the transmission status of the base station before the handover is a DTX state.

The determining module 2103 is configured to determine, according to the transmitting state of the continuous transmission of the base station after receiving the handover of the base station, the time for transmitting the uplink data and/or to switch the transmitting state to the transmitting state of the continuous transmission.

The sending module 2101 is further configured to send the uplink data to the base station according to the time for transmitting the uplink data determined by the determining module 2103 and/or in the transmitting state of the continuous transmission.

Optionally, the receiving module 2102 is further configured to receive a transmit status of the DTX status sent by the base station. The function modules of the UE provided in this embodiment can be used to perform the process of the data sending method shown in FIG. 10. The specific working principle is not described here. For details, refer to the description of the method embodiments.

The UE provided in this embodiment cooperates with the base station provided by the foregoing embodiment to access the cell in time to obtain the service, which reduces the delay of accessing or performing data transmission, and solves the problem that the base station performs a relatively long period of DTX. The problem of the QoS requirements of the UE cannot be met, thereby ensuring the transmission or access of the above data of the UE.

FIG. 22 is a schematic structural diagram of still another UE according to an embodiment of the present invention. As shown in FIG. 22, the UE includes: a transmitter 2201, a receiver 2202, and a processor 2203. The transmitter 2201 is configured to send a service request to the base station.

The receiver 2202 is configured to receive, by the base station, a transmission status of the continuous transmission after the base station switches according to the service request, where the transmission status of the base station before the handover is a DTX state.

The processor 2203 is configured to determine, according to the transmitting status of the continuously transmitted radio signals after the base station is switched by the receiver 2201, the time for transmitting the uplink data and/or the transmitting the state to the transmitting state of the continuous transmission.

The transmitter 2201 is further configured to transmit uplink data to the base station according to a time when the uplink data is transmitted by the processor 2203 and/or in a transmission state of the continuous transmission.

Optionally, the receiver 2202 is further configured to receive a transmit status of a DTX status sent by the base station. Further, the UE further includes: a memory.

The processor 2203 can be used to execute a program of memory storage for implementing control logic or the like of the UE.

The memory can include high speed RAM memory or nonvolatile memory

(non-volatile memory), such as at least one disk storage.

Processor 2203 can be a CPU, or a specific ASIC, or one or more integrated circuits configured to implement embodiments of the present invention.

Optionally, in a specific implementation, the transmitter 2201, the receiver 2202, and the processor 2203 can be connected to each other through a bus and complete communication with each other. The bus can be an ISA bus, a PCI bus, or an EISA bus. The bus can be divided into an address bus, a data bus, a control bus, and the like. For ease of representation, only one thick line is shown in Figure 22, but it does not mean that there is only one bus or one type of bus.

Optionally, in a specific implementation, the transmitter 2201, the receiver 2202, and the processor 2203 can perform the same communication through the internal interface.

Further optionally, the UE may further include an input unit, a display unit, a power module, an audio circuit, and the like in addition to the transmitter 2201, the receiver 2202, the memory, and the processor 2204. The input unit may be a touch panel or other input device, and the display unit may be a display panel or the like.

The UE provided in this embodiment may be used to execute the process of the data sending method shown in FIG. The working principle will not be described again. For details, please refer to the description of the method embodiment.

A person skilled in the art can understand that all or part of the steps of implementing the above method embodiments may be completed by using hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, and the program is executed when executed. The steps of the foregoing method embodiments are included; and the foregoing storage medium includes: a medium that can store program codes, such as a ROM, a RAM, a magnetic disk, or an optical disk.

Finally, it should be noted that the above embodiments are only for explaining the technical solutions of the present invention, and are not intended to be limiting thereof; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that The technical solutions described in the foregoing embodiments may be modified, or some or all of the technical features may be equivalently replaced; and the modifications or substitutions do not deviate from the technical solutions of the embodiments of the present invention. range.

Claims

claims

1. A data receiving method, characterized by including:

Receive the service request sent by the user equipment UE;

According to the service request sent by the UE, the discontinuous transmission DTX configuration is switched from using the first DTX parameter set for discontinuous transmission to using the second DTX parameter set for discontinuous transmission. The first DTX cycle in the first DTX parameter set The active state time is less than the active state time of the second DTX cycle in the second DTX parameter set, or the proportion of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the The proportion of the active state time of the second DTX cycle in the second DTX parameter set in the second DTX cycle;

Send the DTX configuration using the second DTX parameter set for discontinuous transmission to the UE; determine the active state time of the second DTX cycle according to the DTX configuration using the second DTX parameter set for non-continuous transmission;

Receive uplink data sent by the UE within the active time of the second DTX cycle.

2. The method according to claim 1, characterized in that the inactive state time of the first DTX cycle is greater than or equal to the inactive state time of the second DTX cycle.

3. The method according to claim 1 or 2, characterized in that the first DTX period is greater than or equal to the second DTX period.

4. The method according to any one of claims 1 to 3, further comprising: determining that the uplink data of the UE has been sent, and configuring the DTX to use a second DTX parameter set for discontinuous transmission. Switch to using the first DTX parameter set for non-continuous transmission;

sending the DTX configuration for non-continuous transmission using the first DTX parameter set to the

UE o

5. The method according to claim 4, characterized in that: sending the DTX configuration using the second DTX parameter set for discontinuous transmission to the UE includes:

The DTX configuration using the second DTX parameter set for discontinuous transmission is sent to the UE through the first radio resource control protocol RRC dedicated signaling or the first paging message or the first broadcast message; the DTX configuration using the second DTX parameter set is sent to the UE; The DTX configuration for non-continuous transmission of the first DTX parameter set is sent to the UE, including:

The DTX configuration using the first DTX parameter set for discontinuous transmission is sent to the UE through the second RRC dedicated signaling or the second paging message or the second broadcast message.

6. The method according to any one of claims 1-5, characterized in that the method further includes: establishing an RRC connection with the UE according to the service request;

The receiving the uplink data sent by the UE within the active state time of the second DTX cycle includes:

Through the RRC connection, the uplink data sent by the UE is received within the active state time of the second DTX cycle.

7. The method according to any one of claims 1 to 6, characterized in that the service request includes a scheduling request or a random access request.

8. A data sending method, characterized by including:

Send service request to base station;

Receive the DTX configuration for non-continuous transmission using the second non-continuous transmission DTX parameter set sent by the base station, wherein the DTX configuration for non-continuous transmission using the second non-continuous transmission DTX parameter set is the base station according to the The service request is a DTX configuration used after switching from a DTX configuration using the first DTX parameter set for discontinuous transmission, and the activation time of the first DTX cycle in the first DTX parameter set is smaller than the second DTX configuration in the second DTX parameter set. The active state time of the DTX cycle, or the proportion of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than the active state time of the second DTX cycle in the second DTX parameter set. The proportion in the second DTX cycle;

Determine the active state time of the second DTX cycle according to the DTX configuration using the second discontinuous transmission DTX parameter set for discontinuous transmission;

Send uplink data to the base station within the determined active state time of the second DTX cycle.

9. The method according to claim 8, wherein the inactive state time of the first DTX cycle is greater than or equal to the inactive state time of the second DTX cycle.

10. The method according to claim 8 or 9, characterized in that the first DTX period is greater than or equal to the second DTX period.

1 1. The method according to any one of claims 8 to 10, characterized in that, after sending uplink data to the base station within the active time of the second DTX cycle, the method further includes: receiving the data sent by the base station. The first DTX parameter set is used for DTX configuration of discontinuous transmission.

12. The method according to claim 11, wherein the receiving the DTX configuration sent by the base station for discontinuous transmission using the second discontinuous transmission DTX parameter set includes: Receive the first radio resource control protocol RRC dedicated signaling or the first paging message or the first broadcast message sent by the base station, where the first RRC dedicated signaling or the first paging message or the first broadcast message includes the Using the second discontinuous transmission DTX parameter set to perform DTX configuration for discontinuous transmission;

The DTX configuration sent by the receiving base station for discontinuous transmission using the first DTX parameter set includes:

Receive the second RRC dedicated signaling or the second paging message or the second broadcast message sent by the base station, the second RRC dedicated signaling or the second paging message or the second broadcast message including the use of the first DTX Parameter set for DTX configuration of discontinuous transmission.

13. The method according to any one of claims 8 to 12, characterized in that the service request includes a scheduling request or a random access request.

14. A data receiving method, characterized by including:

Receive a service request sent by the user equipment UE for requesting the initiation of the first service, and receive the quality of service QoS level of the first service and/or the resource type required by the first service sent by the UE;

According to the QoS level of the first service and/or the resource type required by the first service, from the set DTX configuration using at least one discontinuous transmission DTX parameter set for discontinuous transmission, determine the The QoS level of the service and/or the resource type required by the first service correspond to the DTX configuration of discontinuous transmission using the third DTX parameter set;

Send the DTX configuration using the third DTX parameter set for discontinuous transmission to the UE; determine the active state time of the third DTX cycle according to the DTX configuration using the third DTX parameter set for non-continuous transmission;

Receive uplink data sent by the UE during the active state time of the third DTX cycle.

15. The method according to claim 14, wherein the receiving the quality of service QoS level of the first service sent by the UE and/or the resource type required for the first service includes:

The radio resource control protocol RRC connection establishment completion message sent by the UE is received, and the RRC connection establishment completion message includes the QoS level of the first service and/or the resource type required by the first service.

16. The method according to claim 14 or 15, characterized in that: sending the DTX configuration using the third DTX parameter set for discontinuous transmission to the UE includes: The DTX configuration using the third DTX parameter set for discontinuous transmission is sent to the UE through RRC dedicated signaling or a paging message or a broadcast message.

17. The method according to any one of claims 14 to 16, characterized in that,

The receiving a service request sent by the user equipment UE for requesting the initiation of a first service includes: receiving a service request sent by the user equipment UE for requesting the initiation of at least one first service; the QoS according to the first service The level and/or the resource type required by the first service is determined from the set DTX configuration of at least one DTX configuration using the non-continuous transmission DTX parameter set for discontinuous transmission, and the QoS level and/or the QoS level of the first service is determined. The DTX configuration using the third DTX parameter set for discontinuous transmission corresponding to the resource type required by the first service includes:

According to the QoS level of the at least one first service and/or the resource type required by the at least one first service, from the set DTX configuration using at least one DTX parameter set for discontinuous transmission, at least one configuration related to the at least one DTX parameter set is determined. The DTX configuration for discontinuous transmission using a fourth DTX parameter set corresponding to the QoS level of the at least one first service and/or the resource type required by the at least one first service;

From the at least one DTX configuration that uses the fourth DTX parameter set for discontinuous transmission, it is determined that the DTX cycle with the longest active state time and the shortest inactive state time of the DTX cycle uses the fourth DTX parameter set for non-continuous transmission. The DTX configuration is used as the DTX configuration using the third DTX parameter set for discontinuous transmission.

18. The method according to any one of claims 14 to 17, characterized in that the method further includes:

If the DTX configuration uses a non-described third DTX parameter set for discontinuous transmission, switch the DTX configuration from using a non-described third DTX parameter set for non-continuous transmission to using the third DTX parameter set for non-continuous transmission. .

19. The method according to any one of claims 14 to 18, characterized in that the at least one DTX parameter set corresponds to different parameter combinations, and the parameter combinations include at least one of QoS level and resource type.

20. The method according to any one of claims 14 to 19, characterized in that the service request includes a scheduling request or a random access request.

21. A data sending method, characterized by including:

Send a service request for requesting to initiate the first service to the base station, and send the The quality of service QoS level of the first service and/or the resource type required by the first service;

Receive a DTX configuration using a third DTX parameter set for discontinuous transmission sent by the base station, where the DTX configuration using the third DTX parameter set for non-continuous transmission is based on the QoS level and/or of the first service by the base station. Or the required resource type of the first service, determined from the set DTX configuration using at least one discontinuous transmission DTX parameter set for discontinuous transmission, is related to the QoS level of the first service and/or the third DTX configuration corresponding to the resource type required by a business;

Determine the active state time of the third DTX cycle according to the DTX configuration using the third DTX parameter set for discontinuous transmission;

Send uplink data to the base station during the active time of the third DTX cycle.

22. The method according to claim 21, wherein said sending the quality of service QoS level of the first service and/or the resource type required by the first service to the base station includes: The base station sends a radio resource control protocol RRC connection establishment completion message, where the RRC connection establishment completion message includes the QoS level of the first service and/or the resource type required by the first service.

23. The method according to claim 21 or 22, wherein the receiving the DTX configuration sent by the base station for discontinuous transmission using the third DTX parameter set includes:

Receive RRC dedicated signaling or paging messages or broadcast messages sent by the base station, where the RRC dedicated signaling or paging messages or broadcast messages include the DTX configuration using the third DTX parameter set for discontinuous transmission.

24. The method according to any one of claims 21 to 23, characterized in that the service request includes a scheduling request or a random access request.

25. A data receiving method, characterized by including:

Receive the service request sent by the user equipment UE;

Switch the transmission state from the discontinuous transmission DTX state to the continuous transmission state according to the service request;

Send the transmission state of the continuous transmission state after the switch to the UE;

In the continuous transmission state after the switching, the uplink data sent by the UE is received.

26. The method according to claim 25, further comprising:

Determine that the uplink data of the UE has been sent;

Switch the transmitting state to the DTX state; The switched transmission state of the DTX state is sent to the UE.

27. The method of claim 25, further comprising:

When the transmission state is switched from the DTX state to the continuous transmission state, the timing is started. At the end of the timing, the transmission state is switched from the continuous transmission state to the DTX state, and the transmission state of the switched DTX state is sent to the UE.

28. The method according to claim 27, characterized in that the method further includes: if a service request sent by another UE is received before the end of the timing, restarting the timing.

29. The method according to any one of claims 25 to 28, characterized in that the service request includes a scheduling request or a random access request.

30. A data sending method, characterized by including:

Send service request to base station;

Receive the transmission state of the continuous transmission after the base station switches according to the service request sent by the base station, wherein the transmission state before the base station switches is the discontinuous transmission DTX state;

Determine the time to send uplink data according to the transmission state of continuous transmission after the base station is switched and/or switch the transmission state to the transmission state of continuous transmission;

The uplink data is sent to the base station according to the determined time to send the uplink data and/or in the transmission state of the continuous transmission.

31. The method of claim 30, further comprising:

Receive the transmission status of the DTX status sent by the base station.

32. A base station, characterized by including:

The receiving module is used to receive the service request sent by the user equipment UE;

a switching module, configured to switch the discontinuous transmission DTX configuration from using the first DTX parameter set for discontinuous transmission to using the second DTX parameter set for discontinuous transmission according to the service request sent by the UE received by the receiving module, The activation time of the first DTX cycle in the first DTX parameter set is less than the activation time of the second DTX cycle in the second DTX parameter set, or the activation time of the first DTX cycle in the first DTX parameter set The proportion of the time in the first DTX cycle is less than the proportion of the active state time in the second DTX cycle in the second DTX parameter set in the second DTX cycle; a sending module, configured to switch the DTX configuration by the switching module The DTX configuration using the second DTX parameter set for non-continuous transmission is sent to the UE;

Determining module, configured to perform non-continuous transmission according to the DTX configuration using the second DTX parameter set Set to determine the active state time of the second DTX cycle;

The receiving module is further configured to receive the uplink data sent by the UE within the activation time of the second DTX cycle determined by the determining module.

33. The base station according to claim 32, wherein the inactive state time of the first DTX cycle is greater than or equal to the inactive state time of the second DTX cycle.

34. The base station according to claim 32 or 33, characterized in that the first DTX period is greater than or equal to the second DTX period.

35. The base station according to any one of claims 32-34, characterized in that,

The switching module is also used to determine that the uplink data transmission of the UE has been completed, and to switch the DTX configuration from using the second DTX parameter set for discontinuous transmission to using the first DTX parameter set for discontinuous transmission. ;

The sending module is also configured to send the DTX configuration using the first DTX parameter set for non-continuous transmission after the switching module switches the DTX configuration using the second DTX parameter set for non-continuous transmission. to the UE.

36. The base station according to claim 35, characterized in that,

The sending module is specifically configured to send the DTX configuration using the second DTX parameter set for discontinuous transmission to the first radio resource control protocol RRC dedicated signaling or the first paging message or the first broadcast message. UE;

The sending module is specifically configured to send the DTX configuration using the first DTX parameter set for discontinuous transmission to the UE through the second RRC dedicated signaling or the second paging message or the second broadcast message. o

37. The base station according to any one of claims 32 to 36, characterized in that the base station further includes a connection establishment module;

The connection establishment module is configured to establish an RRC connection with the UE according to the service request received by the receiving module;

The receiving module is specifically configured to receive the uplink data sent by the UE during the active state time of the second DTX cycle through the RRC connection established by the connection establishment module.

38. The base station according to any one of claims 32 to 37, characterized in that the service request includes a scheduling request or a random access request.

39. A user equipment, characterized by: including: Sending module, used to send service requests to the base station;

The receiving module is configured to receive the DTX configuration for discontinuous transmission using the second non-continuous transmission DTX parameter set sent by the base station, wherein the DTX configuration for non-continuous transmission using the second non-continuous transmission DTX parameter set is the The base station uses the DTX configuration after switching from the DTX configuration using the first DTX parameter set for discontinuous transmission according to the service request sent by the sending module, and the activation time of the first DTX cycle in the first DTX parameter set is less than the DTX configuration. The active state time of the second DTX cycle in the second DTX parameter set, or the proportion of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than that of the second DTX parameter set The ratio of the active state time of the second DTX cycle to the second DTX cycle;

Determining module, configured to determine the activation state time of the second DTX cycle according to the DTX configuration of discontinuous transmission using the second DTX parameter set received by the receiving module;

The sending module is also configured to send uplink data to the base station within the active state time of the second DTX cycle determined by the determining module.

40. The user equipment according to claim 39, wherein the inactive state time of the first DTX cycle is greater than or equal to the inactive state time of the second DTX cycle.

41. The user equipment according to claim 39 or 40, characterized in that the first DTX period is greater than or equal to the second DTX period.

42. The user equipment according to any one of claims 39 to 41, characterized in that the receiving module is also configured to send uplink to the base station during the active state time of the sending module in the second DTX cycle. After receiving the data, the DTX configuration sent by the base station for non-continuous transmission using the first DTX parameter set is received.

43. The user equipment according to claim 42, characterized in that,

The receiving module is specifically configured to receive the first Radio Resource Control Protocol RRC dedicated signaling or the first paging message or the first broadcast message sent by the base station. The first RRC dedicated signaling or the first paging message or The first broadcast message includes a DTX configuration using a second DTX parameter set for discontinuous transmission; the receiving module is specifically configured to receive the second RRC dedicated signaling or the second paging message or the second broadcast message sent by the base station, The second RRC dedicated signaling or the second paging message or the second broadcast message includes the DTX configuration using the first DTX parameter set for discontinuous transmission.

44. The user equipment according to any one of claims 39 to 43, characterized in that the service request includes a scheduling request or a random access request.

45. A base station, characterized by including:

A receiving module configured to receive a service request sent by the user equipment UE for requesting the initiation of the first service, and receive the quality of service QoS level of the first service sent by the UE and/or the service quality required by the first service. Resource Type;

Determining module, configured to use at least one discontinuous transmission DTX parameter set for discontinuous transmission from the set DTX based on the QoS level of the first service received by the receiving module and/or the resource type required by the first service. In the configuration, determine the DTX configuration using the third DTX parameter set for discontinuous transmission corresponding to the QoS level of the first service and/or the resource type required by the first service; a sending module, configured to transmit the The DTX configuration determined by the determination module for non-continuous transmission using the third DTX parameter set is sent to the UE;

The determination module is also configured to determine the activation state time of the third DTX cycle according to the DTX configuration using the third DTX parameter set for discontinuous transmission;

The receiving module is further configured to receive the uplink data sent by the UE within the active state time of the third DTX cycle determined by the determining module.

46. The base station according to claim 45, characterized in that,

The receiving module is specifically configured to receive a radio resource control protocol RRC connection establishment completion message sent by the UE, where the RRC connection establishment completion message includes the QoS level of the first service and/or the information required by the first service. Resource Type.

47. The base station according to claim 45 or 46, characterized in that,

The sending module is specifically configured to send the DTX configuration using the third DTX parameter set for discontinuous transmission to the UE through RRC dedicated signaling or paging messages or broadcast messages.

48. The base station according to any one of claims 45-47, characterized in that,

The receiving module is specifically configured to receive a service request sent by the UE to request the initiation of at least one first service;

The determination module is specifically configured to perform discontinuous transmission from the set DTX parameter set using at least one discontinuous transmission according to the QoS level of the at least one first service and/or the resource type required by the at least one first service. Among the transmitted DTX configurations, determine at least one DTX configuration that uses a fourth DTX parameter set for discontinuous transmission corresponding to the QoS level of the at least one first service and/or the resource type required by the at least one first service. , from the at least one DTX configuration using the fourth DTX parameter set for non-continuous transmission, it is determined that the active state time of the DTX cycle is the longest, and the DTX The DTX configuration that uses the fourth DTX parameter set for discontinuous transmission and has the shortest period of inactive state time is used as the DTX configuration that uses the third DTX parameter set for non-continuous transmission.

49. The base station according to any one of claims 45 to 48, wherein the determining module is further configured to configure the DTX configuration when the DTX configuration uses a non-continuous transmission using a parameter set other than the third DTX parameter set. Switching from using the third DTX parameter set to perform discontinuous transmission to using the third DTX parameter set to perform discontinuous transmission.

50. The base station according to any one of claims 45 to 49, characterized in that the at least one DTX parameter set corresponds to different parameter combinations, and the parameter combinations include at least one of QoS level and resource type.

51. The base station according to any one of claims 45 to 50, characterized in that the service request includes a scheduling request or a random access request.

52. A user equipment, characterized by: including:

A sending module, configured to send a service request to the base station for requesting the initiation of the first service, and send the quality of service QoS level of the first service and/or the resource type required for the first service to the base station;

A receiving module, configured to receive a DTX configuration using a third non-continuous transmission DTX parameter set for non-continuous transmission sent by the base station. The DTX configuration using the third DTX parameter set for non-continuous transmission is the DTX configuration of the base station according to the The QoS level of the first service and/or the required resource type of the first service, determined from the set DTX configuration using at least one DTX parameter set for discontinuous transmission, and the QoS level of the first service and /or DTX configuration corresponding to the resource type required by the first service;

Determining module, configured to determine the activation state time of the third DTX cycle according to the DTX configuration of discontinuous transmission using the third DTX parameter set received by the receiving module;

The sending module is also configured to send uplink data to the base station within the active state time of the third DTX cycle determined by the determining module.

53. The user equipment according to claim 52, characterized in that,

The sending module is specifically configured to send a radio resource control protocol RRC connection establishment completion message to the base station, where the RRC connection establishment completion message includes the QoS level of the first service and/or the information required by the first service. Resource Type.

54. The user equipment according to claim 52 or 53, characterized in that, The receiving module is specifically configured to receive RRC dedicated signaling or paging messages or broadcast messages sent by the base station, where the RRC dedicated signaling or paging messages or broadcast messages include the use of the third DTX parameter set for non- DTX configuration for continuous transmission.

55. The user equipment according to any one of claims 52 to 54, characterized in that the service request includes a scheduling request or a random access request.

56. A base station, characterized by including:

A switching module, configured to switch the transmission state from the discontinuous transmission DTX state to the continuous transmission state according to the service request received by the receiving module;

A sending module, configured to send the transmission state of the continuous transmission state after switching by the switching module to the UE;

The receiving module is also configured to receive uplink data sent by the UE in the continuous transmitting state after switching by the switching module.

57. The base station according to claim 56, characterized in that, the base station further includes a determining module;

The determining module is used to determine that the uplink data transmission of the UE has been completed;

The switching module is also configured to switch the transmission state to the DTX state after the determination module determines that the uplink data transmission of the UE is completed;

The sending module is also configured to send the transmission state of the DTX state after switching by the switching module to the UE.

58. The base station according to claim 56, further comprising:

Timing module, used to start timing when the transmission state is switched from the DTX state to the continuous transmission state;

The switching module is also used to switch the transmission state from the continuous transmission state to the DTX state when the timing module ends;

The sending module is configured to send the transmission state of the DTX state after switching by the switching module to the UE.

59. The base station according to claim 58, characterized in that,

The timing module is also configured to restart timing when the receiving module receives a service request sent by other UE before the timing ends.

60. The base station according to any one of claims 56 to 59, characterized in that the service request includes a scheduling request or a random access request.

61. A user equipment, characterized by: including:

Sending module, used to send service requests to the base station;

A receiving module, configured to receive the transmission status of the continuous transmission after the base station switches according to the service request sent by the base station, wherein the transmission status before the base station switches is the discontinuous transmission DTX state;

Determining module, configured to determine the time to send uplink data based on the transmission status of continuous transmission after switching of the base station received by the receiving module and/or switch the transmission status to the transmission status of continuous transmission;

The sending module is further configured to send uplink data to the base station according to the time for sending uplink data determined by the determining module and/or in a transmitting state of continuous transmission.

62. The user equipment according to claim 61, characterized in that,

The receiving module is also configured to receive the transmission status of the DTX status sent by the base station.

63. A base station, characterized by including:

Receiver, used to receive the service request sent by the user equipment UE;

A processor configured to switch the discontinuous transmission DTX configuration from using the first DTX parameter set for discontinuous transmission to using the second DTX parameter set for discontinuous transmission according to the service request sent by the UE received by the receiver, The activation time of the first DTX cycle in the first DTX parameter set is less than the activation time of the second DTX cycle in the second DTX parameter set, or the activation time of the first DTX cycle in the first DTX parameter set The proportion of the time in the first DTX cycle is less than the proportion of the active state time in the second DTX cycle of the second DTX cycle in the second DTX parameter set; a transmitter, used to switch the DTX configuration of the processor to The DTX configuration using the second DTX parameter set for non-continuous transmission is sent to the UE;

The processor is further configured to determine the activation state time of the second DTX cycle according to the DTX configuration using the second DTX parameter set for non-continuous transmission;

The receiver is further configured to receive uplink data sent by the UE within the active state time of the second DTX cycle determined by the processor.

64. A user equipment, characterized by: including:

Transmitter, used to send service requests to the base station; A receiver configured to receive a DTX configuration for discontinuous transmission using a second non-continuous transmission DTX parameter set sent by the base station, wherein the DTX configuration for non-continuous transmission using the second non-continuous transmission DTX parameter set is The base station uses the DTX configuration after switching from the DTX configuration using the first DTX parameter set for discontinuous transmission according to the service request sent by the sending module, and the activation time of the first DTX cycle in the first DTX parameter set is less than the DTX configuration. The active state time of the second DTX cycle in the second DTX parameter set, or the proportion of the active state time of the first DTX cycle in the first DTX parameter set in the first DTX cycle is less than that of the second DTX parameter set The ratio of the active state time of the second DTX cycle to the second DTX cycle;

A processor configured to determine the active state time of the second DTX cycle according to the DTX configuration received by the receiver using the second DTX parameter set for discontinuous transmission;

The transmitter is also configured to send uplink data to the base station within the active state time of the second DTX cycle determined by the processor.

65. A base station, characterized by including:

A receiver, configured to receive a service request sent by the user equipment UE for requesting to initiate the first service, and receive the quality of service QoS level of the first service sent by the UE and/or the service quality required by the first service. Resource Type;

A processor configured to, according to the QoS level of the first service received by the receiver and/or the resource type required by the first service, select the DTX that uses at least one discontinuous transmission DTX parameter set for discontinuous transmission. In the configuration, determine the DTX configuration using the third DTX parameter set for discontinuous transmission corresponding to the QoS level of the first service and/or the resource type required by the first service; a transmitter, configured to transmit the The DTX configuration determined by the processor using the third DTX parameter set for discontinuous transmission is sent to the UE;

The processor is further configured to determine the active state time of the third DTX cycle according to the DTX configuration using the third DTX parameter set for discontinuous transmission;

The receiver is further configured to receive the uplink data sent by the UE within the active state time of the third DTX cycle determined by the processor.

66. A user equipment, characterized by: including:

A transmitter, configured to send a service request to the base station for requesting the initiation of the first service, and send the quality of service QoS level of the first service and/or the resource type required for the first service to the base station; A receiver, configured to receive a DTX configuration using a third non-continuous transmission DTX parameter set for non-continuous transmission sent by the base station, where the DTX configuration using the third DTX parameter set for non-continuous transmission is the DTX configuration of the base station according to the The QoS level of the first service and/or the required resource type of the first service, determined from the set DTX configuration using at least one DTX parameter set for discontinuous transmission, and the QoS level of the first service and /or DTX configuration corresponding to the resource type required by the first service;

A processor, configured to determine the activation state time of the third DTX cycle according to the DTX configuration received by the receiver using the third DTX parameter set for discontinuous transmission;

The transmitter is also configured to send uplink data to the base station within the active state time of the third DTX cycle determined by the processor.

67. A base station, characterized by including:

Receiver, used to receive the service request sent by the user equipment UE;

A processor, configured to switch the transmission state from the discontinuous transmission DTX state to the continuous transmission state according to the service request received by the receiver;

A transmitter, configured to send the transmission state of the continuous transmission state after the processor is switched to the UE;

The receiver is also configured to receive uplink data sent by the UE in the continuous transmission state after the processor is switched.

68. A user equipment, characterized by including:

Transmitter, used to send service requests to the base station;

A receiver, configured to receive the transmission status of continuous transmission after the base station switches according to the service request sent by the base station, wherein the transmission status before the base station switches is the discontinuous transmission DTX state;

A processor, configured to determine the time to send uplink data based on the transmission status of continuous transmission after switching of the base station received by the receiver and/or switch the transmission status to the transmission status of continuous transmission;

The transmitter is also configured to send uplink data to the base station according to the time of sending uplink data determined by the processor and/or in a transmission state of continuous transmission.