Patent Description:
In a Long Term Evolution (LTE) system, a frequency domain resource of a terminal is allocated in a whole system bandwidth. As the system bandwidth is greatly increased in a 5th Generation (<NUM>) New Radio (NR) system, a transmission bandwidth of the terminal may take up only a part of the system bandwidth.

In current research on <NUM> NR, a concept of a band width part (BWP) has been determined to be introduced to implement the allocation of the frequency domain resource within a range smaller than the system bandwidth. A base station may configure a plurality of BWPs via Radio Resource Control (RRC) signaling, and then dynamically activate a BWP via DL Control Information (DCI). A BWP is based on a parameter set. The parameter set includes a subcarrier interval and a Cyclic Prefix (CP). According to current solutions, only one BWP can be activated for one terminal; and when a new BWP is activated, the previous BWP may be deactivated.

As shown in <FIG>, when BWP1 is in an activated status, if BWP2 is activated, then the BWP1 may change to be deactivated; and when the BWP1 is deactivated, it may return to a default BWP.

According to the existing technical solutions, a plurality of BWPs cannot be activated simultaneously, that is, a plurality of parameter sets cannot be used simultaneously, and when a plurality of types of services are transmitted concurrently, parameters sets of different services cannot be optimized respectively. Moreover, switchover between two parameter sets may also lead to switchover between two BWPs and conversion of a Radio Frequency (RF) bandwidth of a terminal. Due to the conversion of the RF bandwidth, the terminal cannot receive or send data within a period of time and thus a waste of a spectrum resource may be caused.

Related technology is known from R1-<NUM> titled with "Wider Bandwidth Operations", R1-<NUM> titled with "On bandwidth adaptation" and R1-<NUM> titled with "Bandwidth part configuration and frequency resource allocation".

In order to solve the above-mentioned technical problem, the embodiments of the disclosure provide methods and devices for resource configuration, and a computer storage medium.

A method for resource configuration is provided as set forth in claim <NUM>.

A device for resource configuration is provided as set forth in claim <NUM>.

A computer storage medium provided by the embodiments of the disclosure has computer executable instructions stored thereon; and the computer executable instructions may implement, when being executed by a processor, any one of the above-mentioned methods for resource configuration.

In the technical solutions of the embodiments of the disclosure, a terminal may receive first control information from a network device, the first control information including first indication information, and the first indication information being configured to determine at least two DL BWPs or the at least two UL BWPs to be activated; and the terminal may activate the at least two DL BWPs or the at least two UL BWPs according to the first control information. By adopting the technical solutions of the embodiments of the disclosure, a concept of a BWP set is introduced; by configuring the BWP set, a plurality of BWPs in the BWP set may be activated at the same time; and with the utilization of the plurality of activated BWPs to transmit a signal, simultaneous transmission for multiple types of services can be flexibly supported, and the scheduling flexibility and the spectral utilization rate of a system can be improved.

The accompanying drawings are described here to provide a further understanding of the disclosure, and form a part of the disclosure. The schematic embodiments and description of the disclosure are adopted to explain the disclosure, and do not form improper limits to the disclosure. In the drawings:.

For making the characteristics and technical contents of the embodiments of the disclosure understood in more detail, implementation of the embodiments of the disclosure will be described below in combination with the drawings in detail. The drawings are only adopted for description as references and not intended to limit the embodiments of the disclosure.

<FIG> is a first flowchart of a resource configuration method according to embodiments of the disclosure. As shown in <FIG>, the resource configuration method includes the following operations.

At operation <NUM>: a terminal receives first control information from a network device, the first control information including first indication information, and the first indication information being configured to determine at least two DL BWPs to be activated or at least two UL BWPs to be activated.

In the disclosure, the terminal may be any device capable of communicating with a network, such as a mobile phone, a tablet computer, a notebook and a desktop computer.

In the disclosure, the network device may be a base station, such as a gNB in a <NUM> system.

In the disclosure, the first control information may be DCI or a Media Access Control Control Element (MAC CE).

At operation <NUM>: the terminal activates the at least two DL BWPs or the at least two UL BWPs according to the first control information.

In the embodiments of the disclosure, the terminal receives first configuration information from the network device. The first configuration information includes configuration information of at least one DL BWP set or at least one UL BWP set, the DL BWP set includes a plurality of DL BWPs, and the UL BWP set includes a plurality of UL BWPs.

Herein, the configuration information of the BWP set may include a BWP identifier (ID), a frequency domain position, a bandwidth size and a parameter set of each BWP included in the BWP set. The parameter set may include a subcarrier interval and a Cyclic Prefix (CP).

In the disclosure, the first configuration information may be RRC signaling or System Information (SI).

In the embodiments of the disclosure, the operation that the terminal activates the at least two DL BWPs or the at least two UL BWPs according to the first control information is implemented via the following manners.

Manner <NUM>: in response to that the first indication information is indication information of a first BWP set, the terminal activates each BWP in the first BWP set. In a case that the first BWP set is the DL BWP set, each BWP in the first BWP set is the DL BWP; or in a case that the first BWP set is the UL BWP set, each BWP in the first BWP set is the UL BWP.

For example, the first configuration information may include configuration information of a first BWP set for downlink or uplink. The first BWP set may include BWP<NUM>,. , BWPN (N≥<NUM>). Upon reception of the first control information including the indication information of the first BWP set, the terminal may activate BWP<NUM>,. The BWP<NUM>,. , BWPN may be DL activated BWPs or UL activated BWPs.

In the embodiments, the method further includes that: the terminal receives second configuration information from the network device, the second configuration information including first duration information corresponding to the first BWP set; and the terminal deactivates each BWP in the first BWP set in response to that an activated duration of each BWP in the first BWP set reaches a first duration.

For example, the terminal may receive the second configuration information from the network device. The second configuration information may include information of a timer for the first BWP set (set_timer); and after the set_timer expires, the BWP<NUM>,. , BWPN may be deactivated.

In an implementation, the method may further include that: the terminal receives third configuration information from the network device, the third configuration information including second duration information corresponding to a first BWP in the first BWP set; and the terminal deactivates the first BWP in response to that an activated duration of the first BWP reaches a second duration.

For example, the terminal may receive the third configuration information from the network device. The third configuration information may include information of a timer for BWPi(i=<NUM>,. , N) (timeri); and after the timeri expires, the BWPi may be deactivated.

In an implementation, the method may further include that: in response to that each BWP in the first BWP set is deactivated, a default BWP is activated.

For example, in response to that the BWP<NUM>,. , BWPN in the first BWP set are all deactivated, the DL activated BWP or the UL activated BWP may be changed into the default BWP.

Manner <NUM>: in response to determining, based on the first configuration information, that each BWP in a second BWP set meets a predetermined rule and the first indication information is indication information of a second BWP in the second BWP set, the terminal activates each BWP in the second BWP set. In a case that the second BWP set is the DL BWP set, each BWP in the second BWP set is the DL BWP; or in a case that the second BWP set is the UL BWP set, each BWP in the second BWP set is the UL BWP.

For example, the first configuration information may include configuration information of the second BWP set for downlink or uplink. The second BWP set may include BWP<NUM>,. , BWPN (N≥<NUM>). In a case that the BWP<NUM>,. , BWPN (N≥<NUM>) in the second BWP set meet the predetermined rule, upon the reception of the first control information including the indication information of the BWP1, the terminal may activate the BWP<NUM>,. The BWP<NUM>,. , BWPN may be DL activated BWPs or UL activated BWPs.

In an implementation, the method may further include that: the terminal activates the second BWP in response to determining, based on the first configuration information, that each BWP in the second BWP set does not meet the predetermined rule and the first indication information is indication information of the second BWP in the second BWP set. In a case that the second BWP set is the DL BWP set, the second BWP is the DL BWP; or in a case that the second BWP set is the UL BWP set, the second BWP is the UL BWP.

For example, in a case that the BWP<NUM>,. , BWPN (N≥<NUM>) in the configured second BWP set do not meet the predetermined rule, after the terminal receives the first control information including the indication information of the BWP<NUM>, the BWP<NUM> may become the DL activated BWP or the UL activated BWP.

In the disclosure, each BWP in the second BWP set meets the predetermined rule, which may include at least one of the following situations.

For example, the BWP<NUM>,. , BWPN may be consistent in frequency domain position and bandwidth size.

<NUM>) A frequency domain range of each BWP, other than the second BWP, in the second BWP set is within a frequency domain range of the second BWP.

For example, the frequency domain ranges of the BWP<NUM>,. , BWPN may be within the frequency domain range of the BWP<NUM>.

<NUM>) An RF bandwidth capacity of the terminal is capable of simultaneously covering a frequency domain range of each BWP in the second BWP set.

For example, the RF bandwidth capacity of the terminal can simultaneously cover the frequency domain ranges of the BWP<NUM>,.

In an implementation, the method may further include that: the terminal receives fourth configuration information from the network device, the fourth configuration information including third duration information corresponding to the second BWP; and the terminal deactivates each BWP in the second BWP set in response to that an activated duration of the second BWP reaches a third duration.

For example, in response to that the timer for the BWP<NUM> (timer<NUM>) expires, the BWP<NUM>,. , BWPN may be deactivated.

In an implementation, the method may further include that: the terminal receives fifth configuration information from the network device, the fifth configuration information including fourth duration information corresponding to a third BWP in the second BWP set; and the terminal deactivates the third BWP in response to that an activated duration of the third BWP reaches a fourth duration, the third BWP being different from the second BWP.

For example, in response to that the timer for the BWPi (i=<NUM>,. , N) expires, the BWPi may be deactivated.

In an implementation, the method may further include that: in response to that each BWP in the second BWP set is deactivated, a default BWP may be activated.

For example, in response to that the BWP<NUM>,. , BWPN in the second BWP set are all deactivated, the DL activated BWP or the UL activated BWP may be changed into the default BWP.

<FIG> is a second flowchart of a resource configuration method according to embodiments of the disclosure. As shown in <FIG>, the resource configuration method includes the following operation.

At operation <NUM>: a network device sends first control information to a terminal, the first control information including first indication information, and the first indication information being configured to determine at least two DL BWPs to be activated or the at least two UL BWPs to be activated, to enable the terminal to activate the at least two DL BWPs or the at least two UL BWPs according to the first control information.

In an implementation, the method further includes that: the network device sends first configuration information to the terminal, the first configuration information including configuration information of at least one DL BWP set or at least one UL BWP set, the DL BWP set including a plurality of DL BWPs, and the UL BWP set including a plurality of UL BWPs.

In the embodiments of the disclosure, the first indication information is configured to determine the at least two DL BWPs or the at least two UL BWPs to be activated, which is implemented via the following manners.

Manner <NUM>: in response to that the first indication information is indication information of a first BWP set, the first indication information is configured to enable the terminal to activate each BWP in the first BWP set. In a case that the first BWP set is the DL BWP set, each BWP in the first BWP set is the DL BWP; or in a case that the first BWP set is the UL BWP set, each BWP in the first BWP set is the UL BWP.

In the embodiments, the method further includes that: the network device sends second configuration information to the terminal, the second configuration information including first duration information corresponding to the first BWP set. The first duration information is configured to enable, in response to that an activated duration of each BWP in the first BWP set reaches a first duration, the terminal to deactivate each BWP in the first BWP set.

In an implementation, the method may further include that: the network device sends third configuration information to the terminal, the third configuration information including second duration information corresponding to a first BWP in the first BWP set. The second duration information may be configured to enable, in response to that an activated duration of the first BWP reaches a second duration, the terminal to deactivate the first BWP.

Manner <NUM>: in response to it is determined, based on the first configuration information, that each BWP in a second BWP set meets a predetermined rule and the first indication information is indication information of a second BWP in the second BWP set, the first indication information may be configured to enable the terminal to activate each BWP in the second BWP set. In a case that the second BWP set is the DL BWP set, each BWP in the second BWP set is the DL BWP; or in a case that the second BWP set is the UL BWP set, each BWP in the second BWP set is the UL BWP.

In an implementation, in response to it is determined, based on the first configuration information, that each BWP in the second BWP set does not meet the predetermined rule and the first indication information is indication information of the second BWP in the second BWP set, the first indication information may be configured to enable the terminal to activate the second BWP. In a case that the second BWP set is the DL BWP set, the second BWP is the DL BWP; or in a case that the second BWP set is the UL BWP set, the second BWP is the UL BWP.

In an implementation, each BWP in the second BWP set meets the predetermined rule, which may include the following situations:.

In an implementation, the method may further include that: the network device sends fourth configuration information to the terminal, the fourth configuration information including third duration information corresponding to the second BWP. The third duration information may be configured to enable, in response to that an activated duration of the second BWP reaches a third duration, the terminal to deactivate each BWP in the second BWP set.

In an implementation, the method may further include that: the network device sends fifth configuration information to the terminal, the fifth configuration information including fourth duration information corresponding to a third BWP in the second BWP set. The fourth duration information may be configured to enable, in response to that an activated duration of the third BWP reaches a fourth duration, the terminal to deactivate the third BWP, the third BWP being different from the second BWP.

The technical solutions of the disclosure are further described below in combination with specific application examples.

As shown in Table <NUM> and Table <NUM>, the first configuration information is configured with <NUM> DL BWP sets and <NUM> UL BWP sets which includes the <NUM> DL BWPs respectively. The DL BWP set <NUM> includes DL BWP <NUM> and DL BWP <NUM>, and the DL BWP set <NUM> includes DL BWP <NUM> and DL BWP <NUM>. If the first control information includes an ID of the DL BWP set <NUM>, then the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously. If the first control information includes an ID of the DL BWP set <NUM>, then the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously.

Another method for achieving the same effect is as shown in Table <NUM>, that is, two DL BWP sets are configured, and BWPs included in each BWP set are configured.

It is to be understood that the configuration and activation methods of the UL BWP set is the same as those of the DL BWP set.

As shown in <FIG>, when the DL BWP1 and the DL BWP2 belonging to the DL BWP set <NUM> are in an activated status, and when a timer for the DL BWP set <NUM> expires, the DL BWP1 and the DL BWP2 are deactivated simultaneously.

As shown in <FIG>, when the DL BWP1 and the DL BWP2 belonging to the DL BWP set <NUM> are in an activated status and when a timer1 for the DL BWP2 expires, the DL BWP <NUM> may be deactivated; and when a timer2 for the DL BWP1 expires, the DL BWP <NUM> may be also deactivated.

A first predetermined rule is shown in Table <NUM> and <FIG>, that is, each BWP in one BWP set has the same frequency domain position and bandwidth size. The first configuration information is configured with <NUM> DL BWPs. The DL BWP <NUM> and the DL BWP <NUM> are consistent in frequency domain position and bandwidth size to form a DL BWP set. The DL BWP <NUM> and the DL BWP <NUM> are consistent in frequency domain position and bandwidth size to form another DL BWP set. In a case that the first control information includes an ID of the DL BWP1 or an ID of the DL BWP <NUM>, the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously. In a case that the first control information includes an ID of the DL BWP <NUM> or an ID of DL BWP <NUM>, the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously.

A second predetermined rule is shown in Table <NUM> and <FIG>, that is, frequency domain ranges of BWP<NUM>,. , BWPN are within a frequency domain range of BWP<NUM> in one BWP set. The first configuration information is configured with <NUM> DL BWPs. The frequency domain range of the DL BWP <NUM> is within in the frequency domain range of the DL BWP <NUM>. The DL BWP1 and the DL BWP <NUM> are formed into a DL BWP set. The frequency domain range of the DL BWP <NUM> is within in the frequency domain range of the DL BWP <NUM>. The DL BWP3 and the DL BWP <NUM> are formed into another DL BWP set. In a case that the first control information includes an ID of the DL BWP1 or the DL BWP <NUM>, the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously. In a case that the first control information includes an ID of the DL BWP <NUM> or DL BWP <NUM>, the DL BWP <NUM> and the DL BWP <NUM> are activated simultaneously.

As shown in <FIG> and <FIG>, when the DL BWP1 and the DL BWP2 are in an activated status simultaneously and the DL BWP1 and the DL BWP2 have the same frequency domain positions and bandwidth sizes or the frequency domain range of the DL BWP2 is within the frequency domain range of the DL BWP1, and after a timer1 for the DL BWP1 expires, the DL BWP1 and the DL BWP2 are deactivated simultaneously.

As shown in <FIG> and <FIG>, when the DL BWP1 and the DL BWP2 are in an activated status simultaneously and when a timer1 for the DL BWP1 expires, the DL BWP1 may be deactivated and the DL BWP2 may be still in the activated status. When a timer2 for the DL BWP2 expires, the DL BWP2 may be deactivated and the DL BWP1 may be still in the activated status.

<FIG> is a first structural diagram of a resource configuration device according to embodiments of the disclosure. As shown in <FIG>, the resource configuration device includes a first receiving unit <NUM> and an activation unit <NUM>.

The first receiving unit <NUM> is configured to receive first control information from a network device, the first control information including first indication information, and the first indication information being configured to determine at least two DL BWPs to be activated or at least two UL BWPs to be activated.

The activation unit <NUM> is configured to activate the at least two DL BWPs or the at least two UL BWPs according to the first control information.

In the embodiments, the device further includes a second receiving unit <NUM>.

The second receiving unit <NUM> is configured to receive first configuration information from the network device, the first configuration information including configuration information of at least one DL BWP set or at least one UL BWP set, the DL BWP set including a plurality of DL BWPs, and the UL BWP set including a plurality of UL BWPs.

In the embodiments, the activation unit <NUM> is configured to enable, in response to that the first indication information is indication information of a first BWP set, a terminal to activate each BWP in the first BWP set.

In a case that the first BWP set is the DL BWP set, each BWP in the first BWP set is the DL BWP; or in a case that the first BWP set is the UL BWP set, each BWP in the first BWP set is the UL BWP.

In an implementation, the device further includes a third receiving unit <NUM> and a deactivation unit <NUM>.

The third receiving unit <NUM> is configured to receive second configuration information from the network device, the second configuration information including first duration information corresponding to the first BWP set.

The deactivation unit <NUM> is configured to deactivate each BWP in the first BWP set in response to that an activated duration of each BWP in the first BWP set reaches a first duration.

In an implementation, the device may further include a fourth receiving unit <NUM> and the deactivation unit <NUM>.

The fourth receiving unit <NUM> is configured to receive third configuration information from the network device, the third configuration information including second duration information corresponding to a first BWP in the first BWP set.

The deactivation unit <NUM> is configured to deactivate the first BWP in response to that an activated duration of the first BWP reaches a second duration.

In an implementation, the activation unit <NUM> is further configured to activate a default BWP in response to that each BWP in the first BWP set is deactivated.

In an implementation, the activation unit <NUM> is configured to activate each BWP in the second BWP set in response to determining, based on the first configuration information, that each BWP in a second BWP set meets a predetermined rule and the first indication information is indication information of a second BWP in the second BWP set.

In a case that the second BWP set is the DL BWP set, each BWP in the second BWP set may be the DL BWP; or in a case that the second BWP set is the UL BWP set, each BWP in the second BWP set may be the UL BWP.

In a case that the second BWP set is the DL BWP set, the second BWP may be the DL BWP; or in a case that the second BWP set is the UL BWP set, the second BWP may be the UL BWP.

In an implementation, the device may further include a fifth receiving unit <NUM> and the deactivation unit <NUM>.

The fifth receiving unit <NUM> is configured to receive fourth configuration information from the network device, the fourth configuration information including third duration information corresponding to the second BWP.

The deactivation unit <NUM> is configured to deactivate each BWP in the second BWP set in response to that an activated duration of the second BWP reaches a third duration.

In an implementation, the device may further include a sixth receiving unit <NUM> and the deactivation unit <NUM>.

The sixth receiving unit <NUM> is configured to receive fifth configuration information from the network device, the fifth configuration information including fourth duration information corresponding to a third BWP in the second BWP set.

The deactivation unit <NUM> is configured to deactivate the third BWP in response to that an activated duration of the third BWP reaches a fourth duration, the third BWP being different from the second BWP.

In an implementation, the activation unit <NUM> is further configured to activate a default BWP in response to that each BWP in the second BWP set is deactivated.

Those skilled in the art should know that functions realized by each unit in the resource configuration device shown in <FIG> may be understood with reference to related descriptions about the resource configuration method. The functions of each unit in the resource configuration device shown in <FIG> may be realized through a program running in a processor, and may also be realized through a specific logical circuit.

<FIG> is a second structural diagram of a resource configuration device according to embodiments of the disclosure. As shown in <FIG>, the resource configuration device includes a first sending unit <NUM>.

The first sending unit <NUM> is configured to send first control information to a terminal, the first control information including first indication information, and the first indication information being configured to determine at least two DL BWPs to be activated or at least two UL BWPs to be activated to enable the terminal to activate the at least two DL BWPs or the at least two UL BWPs according to the first control information.

In the embodiments, the device further includes a second sending unit <NUM>.

The second sending unit <NUM> is configured to send first configuration information to the terminal, the first configuration information including configuration information of at least one DL BWP set or at least one UL BWP set, the DL BWP set including a plurality of DL BWPs, and the UL BWP set including a plurality of UL BWPs.

In the embodiments, in response to that the first indication information is indication information of a first BWP set, the first indication information is configured to enable the terminal to activate each BWP in the first BWP set.

In the embodiments, the device further includes a third sending unit <NUM>.

The third sending unit <NUM> is configured to send second configuration information to the terminal, the second configuration information including first duration information corresponding to the first BWP set.

The first duration information is configured to enable, in response to that an activated duration of each BWP in the first BWP set reaches a first duration, the terminal to deactivate each BWP in the first BWP set.

In an implementation, the device may further include a fourth sending unit <NUM>.

The fourth sending unit <NUM> is configured to send third configuration information to the terminal, the third configuration information including second duration information corresponding to a first BWP in the first BWP set.

The second duration information is configured to enable, in response to that an activated duration of the first BWP reaches a second duration, the terminal to deactivate the first BWP.

In an implementation, in response to it is determined, based on the first configuration information, that each BWP in a second BWP set meets a predetermined rule and the first indication information is indication information of a second BWP in the second BWP set, the first indication information is configured to enable the terminal to activate each BWP in the second BWP set.

In an implementation, in response to it is determined, based on the first configuration information, that each BWP in the second BWP set does not meet the predetermined rule and the first indication information is the indication information of the second BWP in the second BWP set, the first indication information is configured to enable the terminal to activate the second BWP.

In an implementation, the device may further include a fifth sending unit <NUM>.

The fifth sending unit <NUM> is configured to send fourth configuration information to the terminal, the fourth configuration information including third duration information corresponding to the second BWP.

The third duration information is configured to enable, in response to that an activated duration of the second BWP reaches a third duration, the terminal to deactivate each BWP in the second BWP set.

In an implementation, the device may further include a sixth sending unit <NUM>.

The sixth sending unit <NUM> is configured to send fifth configuration information to the terminal, the fifth configuration information including fourth duration information corresponding to a third BWP in the second BWP set.

The fourth duration information is configured to enable, in response to that an activated duration of the third BWP reaches a fourth duration, the terminal to deactivate the third BWP, the third BWP being different from the second BWP.

When being implemented by software functional modules and sold or used as an independent product, the resource configuration devices of the embodiments of the disclosure may also be stored in a computer-readable storage medium. Based on such an understanding, the technical solutions of the embodiments of the disclosure substantially or the parts making contributions to the conventional art may be embodied as a software product. The computer software product is stored in a storage medium, including a plurality of instructions configured to enable a computer device (which may be a personal computer, a server, a network device or the like) to execute all or part of the method in each embodiment of the disclosure. The storage medium may include various media capable of storing program codes, such as a U disk, a mobile hard disk, a Read Only Memory (ROM), a magnetic disk or an optical disk. Therefore, the embodiments of the disclosure are not limited to any specific hardware and software combination.

Correspondingly, the embodiments of the disclosure further provide a computer storage medium, which has computer executable instructions stored thereon. The computer executable instructions may implement, when being executed by a processor, the above-mentioned resource configuration methods.

<FIG> is a structural diagram of a computer device according to the disclosure. The computer device may be a terminal or may also be a network device. As shown in <FIG>, the computer device <NUM> may include one or more (only one is illustrated in the figure) processors <NUM> (the processor <NUM> may include, but not limited to, a processing device such as a Micro Control Unit (MCU) or a Field Programmable Gate Array (FPGA)), a memory <NUM> configured to store data and a transmission device <NUM> configured for a communication function. Those of ordinary skill in the art should know that the structure shown in <FIG> is only schematic and not intended to limit the structure of the electronic device. For example, the computer device <NUM> may further include components more or fewer than the components shown in <FIG> or has a configuration different from that shown in <FIG>.

The memory <NUM> may be configured to store a software program of application software and a module, for example, a program instruction/module corresponding to a method in the embodiments of the disclosure. The processor <NUM> runs the software program and module stored in the memory <NUM>, thereby executing various functional applications and data processing, namely implementing the above-mentioned method. The memory <NUM> may be a high-speed random access memory or may be a nonvolatile memory, for example, one or more magnetic storage devices, flash memories or other nonvolatile solid-state memories. In some examples, the memory <NUM> may further include a memory arranged remotely relative to the processor <NUM> and the remote memory may be connected to the computer device <NUM> through a network. An example of the network includes, but not limited to, the Internet, an intranet, a local area network, a mobile communication network and a combination thereof.

The transmission device <NUM> is configured to receive or send data through a network. A specific example of the network may include a wireless network provided by a communication provider of the computer device <NUM>. In an example, the transmission device <NUM> includes a Network Interface Controller (NIC), which may be connected with another network device through a base station, thereby communicating with the Internet. In an example, the transmission device <NUM> may be a Radio Frequency (RF) module, configured to communicate with the Internet in a wireless manner.

The technical solutions in the embodiments of the disclosure may be freely combined without conflicts.

In some embodiments provided by the disclosure, it is to be understood that the disclosed method and intelligent device may be implemented in another manner. The device embodiment described above is only schematic, and for example, division of the units is only logic function division, and other division manners may be adopted during practical implementation.

Part of all of the units may be selected according to a practical requirement to achieve the purposes of the solutions of the embodiments.

In addition, each functional unit in each embodiment of the disclosure may be integrated into a second processing unit, each unit may also serve as an independent unit and two or more than two units may also be integrated into a unit. The integrated unit may be implemented in a hardware form and may also be implemented in form of hardware and software functional unit.

Claim 1:
A method for resource configuration, comprising:
receiving, by a terminal, first configuration information from a network device, wherein the first configuration information comprises configuration information of at least one downlink, DL, band width part, BWP, set or at least one uplink, UL, BWP set, the DL BWP set comprises a plurality of DL BWPs, and the UL BWP set comprises a plurality of UL BWPs;
receiving (<NUM>), by the terminal, first control information from the network device, wherein the first control information comprises first indication information, and the first indication information is configured to determine at least two DL BWPs, to be activated or at least two UL BWPs to be activated;
activating (<NUM>), by the terminal, the at least two DL BWPs or the at least two UL BWPs according to the first control information, characterized by comprising:
in response to the first indication information being indication information of a first BWP set, activating, by the terminal, each BWP in the first BWP set simultaneously,
wherein in a case that the first BWP set is the DL BWP set, each BWP in the first BWP set is the DL BWP, or in a case that the first BWP set is the UL BWP set, each BWP in the first BWP set is the UL BWP;
receiving, by the terminal, second configuration information from the network device, wherein the second configuration information comprises first duration information corresponding to the first BWP set; and
deactivating each BWP in the first BWP set simultaneously in response to an activated duration of each BWP in the first BWP set reaching the first duration.