WO2022027651A1

WO2022027651A1 - Radio resource management method, telecommunication system and user equipment

Info

Publication number: WO2022027651A1
Application number: PCT/CN2020/107959
Authority: WO
Inventors: Aijuan Feng; Jia SHENG
Original assignee: JRD Communication (Shenzhen) Ltd.
Priority date: 2020-08-07
Filing date: 2020-08-07
Publication date: 2022-02-10
Also published as: CN116195321A

Abstract

A radio resource management method for a Half-Duplex Frequency Division Duplexing (HD-FDD) transmission between a User Equipment (UE) and a network, and a telecommunication system and the UE implementing the method. At least one guard period (GP) is allocated between a DL mode and a UL mode. Transmissions in the DL mode and the UL mode are performed based on the allocation. A mode switching is performed during the at least one GP to switch between the DL mode and the UL model. In the GP allocation, a duration of the at least one GP is adaptively determined based on characteristics of the UE and/or parameters from the network.

Description

RADIO RESOURCE MANAGEMENT METHOD, TELECOMMUNICATION SYSTEM AND USER EQUIPMENT

BACKGROUND

The invention relates to radio resource management in 5G New Radio (NR) systems, and particularly to guard period (GP) allocation in Half-Duplex Frequency Division Duplexing (HD-FDD) transmissions.

In 3GPP Rel-17, a study Item (SI) “Study on support of reduced capability NR devices” has been started to develop. The scope of this SI includes identification and study of potential User Equipment (UE) complexity reduction techniques and UE power saving and battery lifetime enhancements for reduced capability (RedCap) UEs. Functionality that will enable the performance degradation of such complexity reduction to be mitigated or limited, principles for how to define and constrain such reduced capabilities, and functionality that will allow devices with reduced capabilities to be explicitly identifiable to networks and networks operators and allow operators to restrict their access if desired.

RedCap UEs are generally referred to as the following types: Industrial wireless sensor: pressure sensors, humidity sensors, thermometers, motion sensors, accelerometers, actuators; Surveillance cameras in smart city use case: which covers data collection and processing to more efficiently monitor and control city resources, and to provide services to city residents; and wearable devices: smart watches, rings, eHealth related devices, and medical monitoring devices.

Use cases of the RedCap UEs include novel IoT (Internet of Things) targeted in vertical industries. The usage scenarios locate the boundary between Massive Machine Type Communications (mMTC) and Ultra-Reliable and Low Latency Communications (URLLC) , so the requirements for these services that are higher than Low Power Wide Area (LPWA) (i.e. LTE-M/NB-IOT) but lower than URLCC and Enhanced Mobile BroadBand (eMBB) .

RedCap UEs are expected to be designed in alow complexity manner. The primary goal is to reduce the device cost and complexity as compared to high-end eMBB and URLLC devices of Rel-15/Rel-16. Industrial sensors are the exact examples in this case. The lowest capability considered should be no less than an LTE Category 1bis modem, and the device design is expected to be compactly formed withlowerpower consumption and longer battery lifetime.

Therefore, the following topics are concerned in the study of complexity reduction: Reduced number of UE RX/TX antennas, UE Bandwidth reduction, Half-Duplex-FDD (HD-FDD) , Relaxed UE processing time, and Relaxed UE processing capability.

A summary of a radio resource management method based on HD-FDD transmissions is given in the following sections, accompanied with embodiments of a telecommunication and a UE implementing the method.

SUMMARY

A detailed description is given in the following embodiments with reference to the accompanying drawings.

Embodiments of a radio resource management method are proposed, operable for a Half-Duplex Frequency Division Duplexing (HD-FDD) transmission between a User Equipment (UE) and a network. At least one guard period (GP) is allocated between a DL mode and a UL mode. Transmissions in the DL mode and the UL mode are performed based on the allocation. A mode switching (process) is performed during the at least one GP to switch between the DL mode and the UL model. In the GP allocation, a duration of the at least one GP is adaptively determined based on characteristics of the UE and/or parameters from the network.

Embodiments of the characteristics of the UE may comprisesone or more of a HD-FDD type, a GP type, performance capability of the UE, and power consumption requirement of the UE.

Embodiments of the parameters from the network may comprise OFDM numerologies and Sub-Carrier Spaces (SCSs) .

In an embodiment of the GP allocation, a series of format patterns presenting slot format combinations of the transmissions in the DL mode and the UL mode, and GPs between the DL mode and the UL mode is provided, so that the transmissions in the DL mode and the UL mode are based on the series of format patterns.

The UE may be statically configured through Radio Control Channel (RRC) signaling. The RRC signaling may comprise one or more of periodicity of a format pattern, number of consecutive slots or symbols required respectively for transmissions in the DL mode and the UL mode, andnumber of consecutive slots or symbols required for the mode switching.

In an alternative embodiment, the UE implicitly determines duration of the at least one GP, andperforms the mode switching during the at least one GP.

In an embodiment of a semi-static configuration, a HD-FDD configuration is firstly provided through Radio Control Channel (RRC) signaling, comprising a plurality of format patterns each corresponding to a slot, presenting modes or GPs allocated to each symbol in the slot. The HD-FDD configuration is not activated until a Downlink Control Information (DCI) message is received.

A guarantee timing is determined to execute a Bandwidth Part (BWP) switching (process) based on a mode preference. The BWP switching according to the guarantee timing, such that a time taken by the BWP switching is guaranteed not to affect transmissions of a preferred mode.

The mode preference can be determined by one or more of a DCI, configured by a RRC signaling, or activated by a DCI after configured by the RRC signaling. Alternatively, the mode preference can be determined by one or more of a type of a service being requested by the UE, and a predetermined value in the UE.

In the BWP switching, new parameters are calculated and loaded to prepare for the next mode.

The new parameters is then applied to tune a radio frequency (RF) . No radio transmission or reception is performed during the RF tuning.

The GP allocation has two scenarios. A DL-to-UL GP is allocated for a DL-to-UL mode switching step switching from the DL mode to the UL mode; anda UL-to-DL GP is allocated for the UL-to-DL mode switching step switching from the UL mode to the DL mode.

If the mode preference is the DL mode (DL prioritized) , and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP. A beginning of the first GP is designated to be the guarantee timing. The DL-to-UL mode switching is allocated to start at the guarantee timing, and a UL BWP switching (process) is performed upon completion of the DL-to-UL mode switching.

If the mode preference is the DL mode (DL prioritized) , and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP. An end of the second GP is designated to be the guarantee timing. A start time is calculated based on the guarantee timing and a total time required to perform the UL-to-DL mode switching and a DL BWP switching. The UL-to-DL mode switching is performed at the start time followed by the DL BWP switching.

If the mode preference is the UL mode (UL prioritized) , and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP. An end of the first GP is designated to be the guarantee timing. A start time is calculated based on the guarantee timing and a total time required to perform the DL-to-UL mode switching and a UL BWP switching. The DL-to-UL mode switching is performed at the start time followed by the UL BWP switching.

If the mode preference is the UL mode (UL prioritized) , and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP, a beginning of the second GP is designated to be the guarantee timing. The UL-to-DL mode switching is performed at the guarantee timing. A DL BWP switching is performed upon completion of the UL-to-DL mode switching.

Embodiments of the BWP switching comprises a DL BWP switching (process) and a UL BWP switching (process) . A maximum number of configurable BWPs in each of the DL and UL modes is defined to be 2. If the UL BWP switching is requested during the DL mode, the UL BWP switching is hold off and executed until completion of a next mode switching. Likewise, if the DL BWP switching is requested during the UL mode, the DL BWP switching is hold off and executed until completion of the next mode switching.

In an embodiment, the UE comprises a BWP inactivity timer. If a default BWP is configured when the BWP inactivity timer is expired, the BWP is switched to the default BWP, otherwise, the BWP is switched to an initial BWP if the default BWP is not configured.

In one embodiment, when the HD-FDD transmission is switched to the UL mode, the BWP inactivity timeris suspended at the beginning or end of the DL-to-UL GP. The BWP inactivity timeris resumed at the beginning or end of the UL-to-DL GP.

In an alternative embodiment, when the HD-FDD transmission is switched to the UL mode, the BWP inactivity timer is stopped at the beginning or end of the DL-to-UL GP. The BWP inactivity timer is restarted at the beginning or end of the UL-to-DL GP.

If the BWP switching is triggered at a timing insufficient to complete the BWP switching before mode switching, the request can be ignored. In that case, if the request is triggered by a BWP inactivity timer, the BWP inactivity timer is restarted.

In an alternative embodiment, if the BWP switching is requested at a timing insufficient to complete the BWP switching before mode switching, the BWP switching, and the mode switching are still executed. If the UE is in a RRC connected state, a notification is sent to the network to inform about the BWP switching before execution.

The radio resource management is basically software implementations executed by a UE and the network without hardware manipulations . The UE is preferably a RedCap UE with limited capability. The network is generally referred to as a network node, a base station, a eNB, a gNB or any upper layer node in a telecommunication system. Therefore, embodiments of a telecommunication system and a UE implementing the radio resource management method are also provided. Detailed descriptions about the telecommunication system and the UE would be omitted herein as all the software implementation features are already disclosed in the embodiments of the radio resource management method.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein:

Fig. 1 shows a telecommunication system 100 according to an embodiment of the disclosure;

Fig. 2 is a diagram of a UE 200 according to an embodiment of the disclosure;

Fig. 3 is a flowchart of the radio resource management method according to an embodiment of the disclosure;

Figs. 4a and 4b show embodiments of guard periods 406 implemented in different types;

Fig. 5 shows an embodiment of GP allocation based on a static configuration;

Fig. 6 is a diagram of BWP switch time delay according to an embodiment of the disclosure;

Figs. 7a and 7b show embodiments of mode switching based on different scenarios; and

Fig. 8 is a flow chart of BWP switching according to an embodiment of the disclosure.

DETAILED DESCRIPTION

The following description is of the best-contemplated mode of carrying out the invention. This description is made for the purpose of illustrating the general principles of the invention and should not be taken in a limiting sense. The scope of the invention is best determined by reference to the appended claims.

As described in the background, the bandwidth is reduced in communications with RedCap UEs, consequently, it is to be determined whether the maximum number of BWPs is the same as legacy UEs. Several distinct features are developed in the study of the issues. Embodiments of a radio resource management method are disclosed. A telecommunication system and a UE implementing the radio resource manage method are also introduced.

In the radio resource management method, aguard period (GP) for HD-FDD transmission is proposed, being adaptively adjustable in slot-level, symbol-leveland/or subframe-level. A preferred embodiment is based on the slot-level.

The proposedembodimentsalso support different GPs for different numerologies. Furthermore, more than one type of GPs of the same numerology is supported for different UE characteristics, such as UE computation capability.

A HD-FDD configurationcan be supported in a static manner or in a semi-static manner. A plurality of slot format patternsare defined in the HD-FDD configurationsimilar toTDD slot format patterns, but with the flexible symbols/slot substituted intoGP symbols/slot.

When a BWP switching is combined with themode switching, the starting/end timing of the BWP switchingcan be adaptively allocated to avoid collisions.

Fig. 1shows an embodiment of telecommunication system 100 providing network services, comprising a core network 110 interconnected to one or more gNB-CUs 120a～120b using a control plane interface N2 and a user plane interface N3. A gNB-CU 120a is interconnected to a gNB-DU130a over F1 interface and over Xn (i.e., X2) logical interface to another gNB-CU 120b. The cells 140a～140e are representing areas under coverage of the gNB-DUs or gNB-CUs. The base station as described in the embodiments, conventionally, is known to be a eNB in the LTE standard. In the NR standard, however, a base station becomes a generalized term covering the functions of a gNB-CU and a gNB-DU. The network node as described in the embodiment, can be a more generalized term including the base station and the core network (commonly known as “the network” , “the upper layer” or “the system” ) . Since most of the steps in the embodiments may be jointly accomplished by multiple units throughout multiple layers, and many units may cover the same functions by design, the embodiments are not intended to limit to any actual node which processes the steps. In an embodiment, network services are provided from the core network 110 to the cells 140a～104e. UEs (not shown) located inside the cells 140a～140e, serving as a part of the telecommunication system 100, can therefore implement the disclosed method together with the network nodes, specifically, the gNB-DUs 130a～130b, the gNB-CUs 120a～120b, and the core network 110. It is to be understood that the method in this disclosure is merely software implementations without hardware change. No further introduction is needed because the infrastructure and hardware arrangements of the telecommunication system 100 are following the known standard.

Fig. 2 is a diagram of a UE 200 according to the embodiment of the application. The UE200 generally comprises a transceiver 202, a display 204, a storage 206, a processor 208 and a Subscriber Identity Module (SIM) card 210. The transceiver 202 is also known as an RF module comprising a transmitter (Tx) and a receiver (Rx) , functional for both signal transmissions and receptions since the hardware structure of the transmitter and the receiver can be shared and integrated into one module. The embodiment of the adaptive feedback mechanism is basically software implementations that are presented as software or firmware stored in the storage 206, and executed by the processor 208. Therefore, there is no specific limitation in the hardware structure of the UE 200, which can be a phone, a tablet, a computer, a video streaming device, a set top box or any subscriber enabled communication device.

Fig. 3 is a flowchart of the radio resource management method according to an embodiment of the disclosure. A radio resource management method is proposed, particularly for use in a Half-Duplex Frequency Division Duplexing (HD-FDD) transmission between a UE and a network. In step 301, at least one GP is allocated between a DL mode and a UL mode. The allocation can be executed by the network or the UE depending on different embodiments. In step 303, transmissions in the DL mode and the UL mode are thereby performed based on the allocation. The transmission is performed by the UE in most of the embodiments. In step 305, a mode switching is performed during the at least one GP to switch between the DL mode and the UL mode. To be clarified, the mode switchingand the directions of Tx (UL) and Rx (DL) in this disclosure, are typically based on the perspectiveof the UE. It is to be understood that the modes and Tx/Rx directions on the network side is opposite to that of the UE. The duration of the at least one GP is adaptively determinable based on characteristics of the UE and/or parameters from the network.

Figs. 4a and 4b show embodiments of guard periods 406 implemented in different types. The embodiments of the radio resource management method is basically based on HD-FDD transmissions. Inthe HD-FDD transmissions, a RedCap UE switches between a Downlink (DL) mode and a Uplink (UL) mode, taking significant switching time. Therefore, a guard period (GP) is required for the mode switching. Conventionally, a UE performs a DL-to-UL mode switching by not receiving the last few OFDM symbols in the DL mode. Two HD-FDD operation types (A and B) are specified for the need of guard periods inTS 36.211 6.2.5.

Fig. 4a shows a type A HD-FDD operation implemented by a UE. A DL mode and a UL mode are presented on the time axis t. A UE deliberately stops receiving during aGP406 of a DL subframe 402 to perform a mode switching from the DL mode to the UL mode, such that a UL subframe 404 can be processed immediately upon completion of the DL subframe 402. The duration of the GP 406 is shorter than a duration 410 of the DL subframe 402.

Fig. 4b shows a type B HD-FDD operation. In this case, the entire DL subframes 402a and 402bare allocated as GPs 406. When a DL-to-ULmode switching is desired at the end of a DL transmission, a UEdeliberately stops receiving the last DL subframe 402a of the DL transmission to perform the DL-to-ULmode switching, so the transmission of the UL subframes 404 can be processed immediately upon completion of the DL subframe 402a. Likewise, when a UL-to-DLmode switching is desired at the beginning of a new DL transmission, the UE stops receiving the first subframe 402b of the new DL transmission to perform the mode switching from the UL mode to the DL mode. The DL-to-UL or UL-to-DLmode switching time may involve hardware and software processing timesuch as oscillator adjustment and parameters calculations and applications.

In an embodiment, the duration of the GP is adaptively determinable. Characteristics of the UE and/or parameters from the network may be considered. For example, some UEs may seek to optimize power consumption through a longer switch time, whereas other UEs may prefer to optimize performance and get a shorter switch time. Depending UE capabilities, more than one type guard periods can be set. Thus, characteristics of the UE may comprise one or more of a HD-FDD type, a GP type, performance capability of the UE, and power consumption requirement of the UE. On the other hand, parameters from the network may affect the GP durations. Possible factors may comprise one or more of OFDM numerologies, Sub-Carrier Spaces (SCSs) and cyclic prefixes. The following table shows an embodiment of the GP durations based on difference numerologies and types.

Note that the GPs in the embodiments are described in slots, nevertheless, the unit level can also be symbols or subframes. The values given in the table are merely illustrative and not limited. Variable embodiments can be derived based on different requirements.

In conventional LTE systems, a dynamic scheme for uplink-downlink allocation is used for HD-FDD, however, the UE is expected to receive downlink transmissions in all slots except for those allocated for other functions. If a UE stops the signal reception to perform the mode switching, a HARQ-ACK mechanismmay cause the network (typically gNBs) to perform a retransmission. Significant overheads are therefore induced, including channel collision and data loss. One possible solution is to implement the GP on the network as well. In one embodiment, the UE may transfer its HD-FDD type and GP type to a gNB, causing the gNB to stop data and control signal transmissions during the predetermined GPs. The following exemplary Information Element (IE) shows possible parameters to be implemented in UE capability information element or UE AssistantInformation or other messages/IEs.

hd-FddType ENUMERATED {typeA, typeB} OPTIONAL

hd-GuardPeriodType ENUMERATED {type1, type2} OPTIONAL

A further allocation mechanism is proposed for the HD-FDD transmission to ensure a UE is not transmitting and receiving in the same slot. In one embodiment, step 301 of Fig. 3 may further provide a series of format patterns presenting slot format combinations of the transmissions in the DL/UL modes, and GPs between the DL/UL modes, so that both the UE and the network follow the format pattern to perform the HD-FDD transmission. More embodiments of the format patterns are described hereafter.

Fig. 5 shows an embodiment of GP allocation based on a static configuration. The series of format patterns may be predefined in the static configuration on the network side. The static configuration is transferred to the UE through Radio Control Channel (RRC) signaling, accompanied with other parameters such as periodicity of the format pattern, number of consecutive slots or symbols required respectively for transmissions in the DL mode and the UL mode, and/or number of consecutive slots or symbols required for the mode switching, if any. In Fig. 5, a periodicity 510 of the format pattern over a time axis t is defined. In the periodicity 510. For example, D _SLdefines number of DL slots 502, D _SB defines number of DL symbols 504, t _G defines duration of a guard period 520, U _SB defines number of UL symbols 512, and U _SL defines number of UL slots 514. Thereby a format pattern is formed by the corresponding numbers of UL/DL symbols, slots and/or guard period. The parametersrelated to symbols D _SB and U _SB may be optional.

In another embodiment of static configuration, when the allocation is performed, the UE may implicitly determine duration of a GP, so that the GP determination is immediately effective for the mode switching process. A feedback mechanism may be preferable for the network to be acknowledged about the UE’s GP determination, such that the HD-FDD transmission can work without any collision. The feedback mechanism can be implemented in various ways and is not limited herein.

In another embodiment, a semi-static configuration is proposed. The “semi-static” means that a HD-FDD configuration is provided to the UE through Radio Control Channel (RRC) signaling, but remains inactiveuntil a Downlink Control Information (DCI) message is issued.

An exemplary HD-FDD configuration is shown in the following table, comprising a plurality of format patterns each corresponding to a slot, presenting modes or GPs allocated to each symbol in the slot. The signs “D” , “U” , and “G” are referred to as DL mode, UL mode and GP respectively. Note that the format patterns in the table are merely illustrative but not limited thereto.

In an embodiment, when a DCI message activates the HD-FDD configuration, a SFI-index field value in a DCI format 2_0 indicates a slot format for each slot in a number of slots for each DL mode or each UL mode starting from a slot where the UE detects the DCI format 2_0.

Fig. 6 is a diagram of BWP switch time delay according to an embodiment of the disclosure. A BWP switching process can be divided into several stages each consuming a certain period of time. As shown on the time axis t in Fig. 6, a BWP switching process is triggered at slot n. In stage 602, an Rx operation is performed. The Rx operation isgenerally referred to as signal receptions such as RRC base or DCI base, and the detailed calculation are respectively varied by scenarios which would be omitted herein. In stage 604, the message parsing stage, the received signal takes some parsing time to acquire detailed parameters required for the BWP switching. In step 606, the new parameter calculation stage, time is taken to process and load the newly acquired parameters in preparation of a RF tuning process. In stage 608, time is taken to perform the RF tuning process by applying the new parameters. The time taken from stages 604 to 608 are generalized as a BWP switch delay T _BWP. Note that the stage 608 is in an interruption period 610, which means that the Rx of the UE is not available for any data transmission and reception during the period. A new transmission 612 cannot be started until the total delay timeT _finalends at slot n+y. Detailed calculations of the BWP switch delay T _BWP and the total delay time T _finalcan be acquired from the specs which would be omitted herein, and the technique introduced herein can be incorporated in the embodiments described in Figs. 7a and 7b.

In conventional NR, a UE can be configured up to four BWP in each of the DL and UL modes. The RedCap UEs are likely to support BWs of 20MHz in FR1 and 50 to 100MHz in FR2. Since the bandwidth is reduced, an embodiment of the Redcap UEproposes a maximum number of configurable BWPsto be 2, which means a UE can be configured up to two BWPs in each of the DL and UL modes.

Both BWP and mode switching processes involve adjustments or controls of radio frequency modules (RF) . Typically, these are different types of RF tuning. A BWP switch is normally referred to as RF tuning in Tx or Rx only. The DL-to-UL/UL-to-DL mode switching processesarereferred to as RF tuning with Tx-to-Rx or Rx-to-Tx. As mentioned above, it will take some amount of time to complete both BWP switching and mode switching, so there may be a conflict. For example, when UE is in the DL mode and configured with a DL-to-ULmode switching, a DL BWP switching is also triggered at the same time. If the UE cannot finish the BWP switchingbefore the GP of DL-to-ULmode switching, there will be conflicts.

An embodiment proposes a guarantee timing to solve the issue. A guarantee timing to execute a Bandwidth Part (BWP) switching is determined based on a mode preference. The BWP switching is executed according to the guarantee timingsuch that a time taken by the BWP switching is guaranteed not to affect transmissions of a preferred mode.

Figs. 7a and 7b show embodiments of mode switching based on different scenarios. The mode preference is an indication of which mode is prioritized and must not be affected, comprising two scenarios, DL prioritizedand UL prioritized. In an embodiment, the mode preference can be determined by a DCI, configured by a RRC signaling, or activated by a DCI after configured by the RRC signaling. In another embodiment, the mode preference can be determined by a type of a service being requested by the UE, or based on a predetermined value in the UE.

Note that the mode switching (process) can be understood as comprising two types, a Downlink-to-Uplink (DL-to-UL) mode switching and a Uplink-to-Downlink (UL-to-DL) mode switching. In an embodiment, a DL-to-UL GP is allocated for theDL-to-UL mode switching to switch from the DL mode to the UL mode, anda UL-to-DL GP is allocated for the UL-to-DL mode switching to switchfrom the UL mode to the DL mode.

Fig. 7a shows an embodiment when the mode preference is DL prioritized. In the DL mode, a plurality of DL processes 702 are proceeded and followed by a GP 710 to switch to the UL mode. In the UL mode, a plurality of UL processes 704 are proceeded andfollowed by a GP 720 to switch to the DL mode, so as to proceed more DL processes 702.

In Fig. 7a, when the mode is switchedduring the first GP 710, the beginning of the first GP 710 is designated to be the guarantee timing P ₁. ADL-to-UL mode switching is allocated to be started at the guarantee timing P ₁. Since a UL BWP switching cannot be performed before the DL-to-UL mode switching because the Tx state is not yet configured for the UL mode, the UL BWP switching is processed upon completion of the DL-to-UL mode switching. The total time consumed for the DL-to-UL mode switching and the UL BWP switching is shown as t ₁ starting from the guarantee timing P ₁. The total timet ₁ is case dependent and variable based on different cases. In most cases, the length of the GP 710 is sufficient to cover the total time t ₁. Even if the total timet ₁ exceeds the GP 710, the DL transmission is not affected as expected by the mode preference.

Further in Fig. 7a, when the mode is switched from the UL mode to the DL mode in the second GP 720, the end of the second GP 720 is designated to be the guarantee timing P ₂, which means all switching processes should be complete before the guarantee timing P ₂, such that the DL processes 702 after the guarantee timing P ₂ are guaranteed not to be affected. A start time is calculated based on the guarantee timingP ₂ and a total time t ₂required to perform the UL-to-DL mode switching and a DL BWP switching. The UL-to-DLmode switching is allocated to be start at the start time, followed by the DL BWP switching. With such an arrangement, the DL BWP switching is guaranteed to be finished no later than the guarantee timing P ₂.

Fig. 7b shows an embodiment when the mode preference is UL prioritized. when the mode is switched from the DL mode to the UL mode in the first GP 710, the end of the first GP 710 is designated to be the guarantee timing P ₃, which means all switching processes should be complete before the guarantee timing P ₃, such that the UL processes 704 after the guarantee timing P ₃are guaranteed not to be affected. A start time is calculated based on the guarantee timingP ₃ and a total time t ₃required to perform the DL- to-UL mode switching and a UL BWP switching. The DL-to-ULmode switching is allocated to be start at the start time, followed by the UL BWP switching. With such an arrangement, the DL BWP switching is guaranteed to be finished no later than the guarantee timing P ₃.

Also, in Fig. 7b, when the mode is switched during thesecond GP 720, the beginning of the second GP 720 is designated to be the guarantee timing P ₄. AUL-to-DL mode switching is allocated to be started at the guarantee timing P ₄. Since aDL BWP switching cannot be performed before the UL-to-DL mode switching because the Rx state is not yet configured for the DL mode, the DL BWP switching is processed upon completion of the UL-to-DL mode switching. The total time consumed for the DL-to-UL mode switching and the UL BWP switching is shown as t ₄ starting from the guarantee timing P ₄. The total time t ₄ is case dependent and variable based on different cases. In most cases, the length of the second GP 20 is sufficient to cover the total time t ₄. Even if the total time t ₄ exceeds the second GP 720, the DL transmission is not affected as expected by the mode preference.

Fig. 8 is a flow chart of BWP switching according to an embodiment of the disclosure. Embodiments are provided to handle some exceptions during the BWP switching. For example, when the UE is configured with bwp-InactivityTimer, if the bwp-InactivityTimer associated with the active DL BWP expires, UE will switch to the default DL BWP if configured; Otherwise UE will switch to the initial DL BWP. If the timer is still running after UE switches to the uplink, it may cause an unnecessary switch or even timer expiration while UE is in the UL mode. There are two options:

Option#1: Suspend bwp-InactivityTimer when the guard period of D-to-U begins or ends; Resume it when the guard period of U-to-D begins or ends.

Option#2: Stop bwp-InactivityTimer when the guard period of D-to-U begins or ends;

Restart it when the guard period of U-to-D begins or ends.

As summarized in Fig. 8, it is determined whether a default BWP is configured when the BWP inactivity timer is expired in step 801. Step 803 switches to the default BWP if the default BWP is configured, and step 805 switches to an initial BWP if the default BWP is not configured.

In some cases, the BWP switching may not be able to be processed immediately. Note that the BWP switching (processes) herein is known to comprise a DL BWP switching and a UL BWP switching. In conventional RRC (re-) configuration of firstActiveDownlinkBWP-Id and/or firstActiveUplinkBWP-Id for SpCell or activation of an SCell, the DL BWP and/or UL BWP indicated by firstActiveDownlinkBWP-Id and/or firstActiveUplinkBWP-Id respectively (as specified in TS 38.331 [5] ) should be active. That is, RRC signaling can trigger both DL BWP switch and UL BWP switch at the same time. Upon initiation of the random access procedure, if PRACH occasions are not configured, UE will switch UL BWP to BWP indicated by initialUplinkBWP, and switch the active DL BWP to BWP indicated by initialDownlinkBWP.

In the embodiment, since the RF module in HD-FDD transmissions can only work in one of the Rx or Tx at a time, only DL or UL BWP switch can be performed at a time. When the UE is in the DL mode, the UL BWP switchinghold off until the RF is tuned to Tx mode when next mode switching is taken place. Conversely, when the UE is in the UL mode, the DL BWP switching is hold off until the RF module is tuned to Rx mode when next mode switching is taken place. The embodiment here can be incorporated with the embodiments in Figs. 7a and 7b to fully accomplish the BWP switching (processes) .

Further embodiments are provided to handle further exceptions. For example, the case may happen when a BWP switching is triggered at a time point with insufficient remaining time in the DL modefor theBWP switching. The remaining time can include the guard period or not. Conventionally, a scheduler of the network (gNB) should ensure a UE can complete a BWP switching in time when delivering the trigger message, however, exceptions may occur, for example, when the BWP switching is triggered by the UE (such as Timer-based switch) . Embodiments of different solutions are proposed.

Option#1: the UE ignores the BWP switching trigger. If the BWP switching is triggered by an inactivity timer (bwp-InactivityTimer) , restart the inactivity timer.

Option#2: keep processing the BWP switching, but the mode switching must be performed immediately upon completion of the BWP switching. If the UE is in the RRC connected state, UE notifies the network (gNB) before starting the BWP switching to keep the communication in sync.

Option#3: the UE proceeds actions based on predetermined rules defined bythe network (gNB) .

Option#4: the UE proceeds actions based on predetermined rules defined in the specification or the UE itself.

While the application has been described by way of example and in terms of preferred embodiment, it is to be understood that the invention is not limited thereto. To the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art) . Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.

Claims

A radio resource management method for a Half-Duplex Frequency Division Duplexing (HD-FDD) transmission between a User Equipment (UE) and a network, comprising:

allocating at least one guard period (GP) between a DL mode and a UL mode; performing transmissions in the DL mode and the UL mode based on the allocation;

performing a mode switching during the at least one GP to switch between the DL mode and the UL model; wherein:

the step of allocation comprises adaptively determining duration of the at least one GP based on characteristics of the UE and/or parameters from the network.
The radio resource management method as claimed in claim 1, wherein characteristics of the UE comprises one or more of a HD-FDD type, a GP type, performance capability of the UE, and power consumption requirement of the UE.
The radio resource management method as claimed in claim 1, wherein parameters from the network comprise OFDM numerologies and Sub-Carrier Spaces (SCSs) .
The radio resource management method as claimed in claim 1, wherein the step of allocation comprises:

providing a series of format patterns presenting slot format combinations of the transmissions in the DL mode and the UL mode, and GPs between the DL mode and the UL mode; wherein transmissions in the DL mode and the UL mode are based on the series of format patterns.
The radio resource management method as claimed in claim 4, wherein the step of allocation comprises: statically configuring the UE through Radio Control Channel (RRC) signaling; wherein the RRC signaling comprises one or more of periodicity of a format pattern, number of consecutive slots or symbols required respectively for transmissions in the DL mode and the UL mode, andnumber of consecutive slots or symbols required for the mode switching.
The radio resource management method as claimed in claim 1, wherein:

the step of allocation comprises: the UE implicitly determining duration of the at least one GP; and

the UE performing the mode switching during the at least one GP.
The radio resource management method as claimed in claim4, wherein the step of allocation comprises:

providing a HD-FDD configuration through Radio Control Channel (RRC) signaling, wherein the HD-FDD configuration comprises a plurality of format patterns each corresponding to a slot, presenting modes or GPs allocated to each symbol in the slot; and

activating the HD-FDD configuration through a Downlink Control Information (DCI) message to provide the format patterns.
The radio resource management method as claimed in Claim1, further comprising:

determining a guarantee timing to execute a Bandwidth Part (BWP) switching based on a mode preference, such that a time taken by the BWP switching is guaranteed not to affect transmissions of a preferred mode; and

executing the BWP switching according to the guarantee timing.
The radio resource management method as claimed in Claim 8, wherein the mode preference is determined by one or more of a DCI, configured by a RRC signaling, or activated by a DCI after configured by the RRC signaling.
The radio resource management method as claimed in Claim 8, wherein the mode preference is determined by one or more of a type of a service being requested by the UE, and a predetermined value in the UE.
The radio resource management method as claimed in Claim 8, the BWP switching comprises:

calculating and loading new parameters to prepare for the next mode; and

applying the new parameters to tune a radio frequency (RF) ; wherein no radio transmission or reception is performed during the RF tuning.
The radio resource management method as claimed in Claim 8, wherein the step of allocation comprises:

allocating a DL-to-UL GP for a DL-to-UL mode switching step switching from the DL mode to the UL mode; and

allocating a UL-to-DL GP for the UL-to-DL mode switching step switching from the UL mode to the DL mode.
The radio resource management method as claimed in Claim 12, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP:

determination of the guarantee timing comprisesdesignating a beginning of the first GP to be the guarantee timing;

the mode switching comprises:

performing the DL-to-UL mode switching at the guarantee timing; and

performing a UL BWP switching upon completion of the DL-to-UL mode switching.
The radio resource management method as claimed in Claim 12, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP:

determination of the guarantee timing comprises designating an end of the second GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the UL-to-DL mode switching and a DL BWP switching; and

the mode switching comprises performing the UL-to-DL mode switching at the start time followed by the DL BWP switching.
The radio resource management method as claimed in Claim 12, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP:

determination of the guarantee timing comprises designating an end of the first GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the DL-to-UL mode switching and a UL BWP switching; and

the mode switching comprises performing the DL-to-UL mode switching at the start time followed by the UL BWP switching.
The radio resource management method as claimed in Claim 12, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP:

determination of the guarantee timing comprises designating a beginning of the second GP to be the guarantee timing;

the mode switching comprises performing the UL-to-DL mode switching at the guarantee timing; and

performing a DL BWP switching upon completion of the UL-to-DL mode switching
The radio resource management method as claimed in Claim 8, wherein:

the BWP switching comprises a DL BWP switching and a UL BWP switching, and defining a maximum number of configurable BWPs in each of the DL and UL modesto be 2; and

the step of BWP switching comprises:

if the UL BWP switching is requested during the DL mode, holding off the UL BWP switching and scheduling the UL BWP switching to be executed upon completion of a next mode switching; and

if the DL BWP switching is requested during the UL mode, holding off the DL BWP switching and scheduling the DL BWP switching to be executed upon completion of the next mode switching.
The radio resource management method as claimed in Claim 12, wherein the UE comprises a BWP inactivity timer; and the BWP switching comprises:

determining if a default BWP is configured when the BWP inactivity timer is expired;

switching to the default BWP if the default BWP is configured; and

switching to an initial BWP if the default BWP is not configured.
The radio resource management method as claimed in Claim 18, further comprising:

when the HD-FDD transmission is switched to the UL mode, suspending the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

resuming the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The radio resource management method as claimed in Claim 18, further comprising:

when the HD-FDD transmission is switched to the UL mode, stopping the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

restarting the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The radio resource management method as claimed in Claim 8, further comprising:

If the BWP switching is triggered at a timing insufficient to complete the BWP switching before mode switching, ignoring the request; and

If the request is triggered by a BWP inactivity timer, restarting the BWP inactivity timer.
The radio resource management method as claimed in Claim 8, further comprising:

if the BWP switching is requested at a timing insufficient to complete the BWP switching before mode switching, executing the BWP switching and the mode switching; and

if the UE is in a RRC connected state, notifying the network about the BWP switching before execution.
Atelecommunication systemcomprising a UE and a network, performing a Half-HD-FDDtransmission with radio resource managementwiththe UE and the network, the HD-FDD transmission comprising:

allocating at least one guard period (GP) between a DL mode and a UL mode; performing transmissions in the DL mode and the UL mode based on the allocation;

performing a mode switching during the at least one GP to switch between the DL mode and the UL model; wherein:

the step of allocation comprises adaptively determining duration of the at least one GP based on characteristics of the UE and/or parameters from the network.
The telecommunication system as claimed in claim 23, wherein characteristics of the UE comprises one or more of a HD-FDD type, a GP type, performance capability of the UE, and power consumption requirement of the UE.
The telecommunication system as claimed in claim 23, wherein parameters from the network comprise OFDM numerologies and Sub-Carrier Spaces (SCSs) .
The telecommunication system as claimed in claim 23, further performing the step of allocation comprising:

providing a series of format patterns presenting slot format combinations of the transmissions in the DL mode and the UL mode, and GPs between the DL mode and the UL mode; wherein transmissions in the DL mode and the UL mode are based on the series of format patterns.
The telecommunication system as claimed in claim 26, further performing the step of allocation comprising: statically configuring the UE through Radio Control Channel (RRC) signaling; wherein the RRC signaling comprises one or more of periodicity of a format pattern, number of consecutive slots or symbols required respectively for transmissions in the DL mode and the UL mode, and number of consecutive slots or symbols required for the mode switching.
The telecommunication system as claimed in claim 23, further performingthe step of allocation comprising: the UE implicitly determining duration of the at least one GP, andperforming the mode switching during the at least one GP.
The telecommunication system as claimed in claim26, further performing the step of allocation comprising:

providing a HD-FDD configuration through Radio Control Channel (RRC) signaling, wherein the HD-FDD configuration comprises a plurality of format patterns each corresponding to a slot, presenting modes or GPs allocated to each symbol in the slot; and

activating the HD-FDD configuration through a Downlink Control Information (DCI) message to provide the format patterns.
The telecommunication system as claimed in Claim 23, further performing the steps of :

determining a guarantee timing to execute a Bandwidth Part (BWP) switching based on a mode preference, such that a time taken by the BWP switching is guaranteed not to affect transmissions of a preferred mode; and

executing the BWP switching according to the guarantee timing.
The telecommunication system as claimed in Claim 30, wherein the mode preference is determined by one or more of a DCI, configured by a RRC signaling, or activated by a DCI after configured by the RRC signaling.
The telecommunication system as claimed in Claim 30, wherein the mode preference is determined by one or more of a type of a service being requested by the UE, and a predetermined value in the UE.
The telecommunication system as claimed in Claim 30, further performing the BWP switching comprising:

calculating and loading new parameters to prepare for the next mode; and

applying the new parameters to tune a radio frequency (RF) ; wherein no radio transmission or reception is performed during the RF tuning.
The telecommunication system as claimed in Claim 30, further performing the step of allocation comprising:

allocating a DL-to-UL GP for a DL-to-UL mode switching step switching from the DL mode to the UL mode; and

allocating a UL-to-DL GP for the UL-to-DL mode switching step switching from the UL mode to the DL mode.
The telecommunication system as claimed in Claim 34, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP, the telecommunication systemfurther performs the steps of:

designating a beginning of the first GP to be the guarantee timing;

the mode switching comprises:

performing the DL-to-UL mode switching at the guarantee timing; and

performing a UL BWP switching upon completion of the DL-to-UL mode switching.
The telecommunication system as claimed in Claim 34, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP, the telecommunication systemfurther performs the steps of:

designating an end of the second GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the UL-to-DL mode switching and a DL BWP switching; and

performing the UL-to-DL mode switching at the start time followed by the DL BWP switching.
The telecommunication system as claimed in Claim 34, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP, the telecommunication systemfurther performs the steps of:

designating an end of the first GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the DL-to-UL mode switching and a UL BWP switching; and

performing the DL-to-UL mode switching at the start time followed by the UL BWP switching.
The telecommunication system as claimed in Claim 34, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP, the telecommunication systemfurther performs the steps of:

designating a beginning of the second GP to be the guarantee timing;

the mode switching comprises performing the UL-to-DL mode switching at the guarantee timing; and

performing a DL BWP switching upon completion of the UL-to-DL mode switching
The telecommunication system as claimed in Claim 30, wherein the BWP switching comprises a DL BWP switching and a UL BWP switching, and defining a maximum number of configurable BWPs in each of the DL and UL modes to be 2;

the telecommunication systemfurther performs the steps of:

if the UL BWP switching is requested during the DL mode, holding off the UL BWP switching and scheduling the UL BWP switching to be executed upon completion of a next mode switching; and

if the DL BWP switching is requested during the UL mode, holding off the DL BWP switching and scheduling the DL BWP switching to be executed upon completion of the next mode switching.
The telecommunication system as claimed in Claim 34, wherein the UE comprises a BWP inactivity timer; and the telecommunication systemfurther performs the steps of:

determining if a default BWP is configured when the BWP inactivity timer is expired;

switching to the default BWP if the default BWP is configured; and

switching to an initial BWP if the default BWP is not configured.
The telecommunication system as claimed in Claim 40, further performing the steps of:

when the HD-FDD transmission is switched to the UL mode, suspending the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

resuming the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The telecommunication system as claimed in Claim 40, further performing the steps of:

when the HD-FDD transmission is switched to the UL mode, stopping the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

restarting the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The telecommunication system as claimed in Claim 30, further performing the steps of:

if the BWP switching is triggered at a timing insufficient to complete the BWP switching before mode switching, ignoring the request; and

if the request is triggered by a BWP inactivity timer, restarting the BWP inactivity timer.
The telecommunication system as claimed in Claim 30, further performing the steps of:

if the BWP switching is requested at a timing insufficient to complete the BWP switching before mode switching, executing the BWP switching and the mode switching; and

if the UE is in a RRC connected state, notifying the network about the BWP switching before execution.
A UE, performing a Half-HD-FDD transmission with radio resource management with a network, the HD-FDD transmission with radio resource management comprising:

allocating at least one guard period (GP) between a DL mode and a UL mode; performing transmissions in the DL mode and the UL mode based on the allocation;

performing a mode switching during the at least one GP to switch between the DL mode and the UL model; wherein:

the step of allocation comprises adaptively determining duration of the at least one GP based on characteristics of the UE and/or parameters from the network.
The UE as claimed in claim 45, wherein characteristics of the UE comprises one or more of a HD-FDD type, a GP type, performance capability of the UE, and power consumption requirement of the UE.
The UE as claimed in claim 45, wherein parameters from the network comprise OFDM numerologies and Sub-Carrier Spaces (SCSs) .
The UE as claimed in claim 45, performing the HD-FDD transmission with radio resource management further comprising:

providing a series of format patterns presenting slot format combinations of the transmissions in the DL mode and the UL mode, and GPs between the DL mode and the UL mode; wherein transmissions in the DL mode and the UL mode are based on the series of format patterns.
The UE as claimed in claim 48, performing the HD-FDD transmission with radio resource management further comprising the step of allocation further comprising:

statically configuring the UE through Radio Control Channel (RRC) signaling; wherein the RRC signaling comprises one or more of periodicity of a format pattern, number of consecutive slots or symbols required respectively for transmissions in the DL mode and the UL mode, and number of consecutive slots or symbols required for the mode switching.
The UE as claimed in claim 45, performing the HD-FDD transmission with radio resource management further comprising the step of allocation further comprising:

the UE implicitly determining duration of the at least one GP, and performing the mode switching during the at least one GP.
The UE as claimed in claim48, performing the HD-FDD transmission with radio resource management further comprising the step of allocation further comprising:

providing a HD-FDD configuration through Radio Control Channel (RRC) signaling, wherein the HD-FDD configuration comprises a plurality of format patterns each corresponding to a slot, presenting modes or GPs allocated to each symbol in the slot; and

activating the HD-FDD configuration through a Downlink Control Information (DCI) message to provide the format patterns.
The UE as claimed in Claim 45, performing the HD-FDD transmission with radio resource management further comprising:

determining a guarantee timing to execute a Bandwidth Part (BWP) switching based on a mode preference, such that a time taken by the BWP switching is guaranteed not to affect transmissions of a preferred mode; and

executing the BWP switching according to the guarantee timing.
The UE as claimed in Claim 52, wherein the mode preference is determined by one or more of a DCI, configured by a RRC signaling, or activated by a DCI after configured by the RRC signaling.
The UE as claimed in Claim 52, wherein the mode preference is determined by one or more of a type of a service being requested by the UE, and a predetermined value in the UE.
The UE as claimed in Claim 52, performing the HD-FDD transmission with radio resource management further comprising the BWP switching comprising:

calculating and loading new parameters to prepare for the next mode; and

applying the new parameters to tune a radio frequency (RF) ; wherein no radio transmission or reception is performed during the RF tuning.
The UE as claimed in Claim 52, performing the HD-FDD transmission with radio resource management further comprising the step of allocation further comprising:

allocating a DL-to-UL GP for a DL-to-UL mode switching step switching from the DL mode to the UL mode; and

allocating a UL-to-DL GP for the UL-to-DL mode switching step switching from the UL mode to the DL mode.
The UE as claimed in Claim 56, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP, the UE performs the HD-FDD transmission with radio resource management further comprising:

designating a beginning of the first GP to be the guarantee timing;

the mode switching comprises:

performing the DL-to-UL mode switching at the guarantee timing; and

performing a UL BWP switching upon completion of the DL-to-UL mode switching.
The UE as claimed in Claim 56, wherein if the mode preference is the DL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP, the UEperforms the HD-FDD transmission with radio resource management further comprising:

designating an end of the second GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the UL-to-DL mode switching and a DL BWP switching; and

performing the UL-to-DL mode switching at the start time followed by the DL BWP switching.
The UE as claimed in Claim 56, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the DL mode to the UL mode during a first GP, the UEperforms the HD-FDD transmission with radio resource management further comprising:

designating an end of the first GP to be the guarantee timing;

calculating a start time based on the guarantee timing and a total time required to perform the DL-to-UL mode switching and a UL BWP switching; and

performing the DL-to-UL mode switching at the start time followed by the UL BWP switching.
The UE as claimed in Claim 56, wherein if the mode preference is the UL mode, and the HD-FDD transmission is being switched from the UL mode to the DL mode during a second GP, the UEperforms the HD-FDD transmission with radio resource management further comprising:

designating a beginning of the second GP to be the guarantee timing;

the mode switching comprises performing the UL-to-DL mode switching at the guarantee timing; and

performing a DL BWP switching upon completion of the UL-to-DL mode switching
The UE as claimed in Claim 52, wherein the BWP switching comprises a DL BWP switching and a UL BWP switching, and defining a maximum number of configurable BWPs in each of the DL and UL modes to be 2; and the UEperforms the HD-FDD transmission with radio resource management further comprising:

if the UL BWP switching is requested during the DL mode, holding off the UL BWP switching and scheduling the UL BWP switching to be executed upon completion of a next mode switching; and

if the DL BWP switching is requested during the UL mode, holding off the DL BWP switching and scheduling the DL BWP switching to be executed upon completion of the next mode switching.
The UE as claimed in Claim 56, wherein the UE comprises a BWP inactivity timer; and the UE performs the HD-FDD transmission with radio resource management further comprising:

determining if a default BWP is configured when the BWP inactivity timer is expired;

switching to the default BWP if the default BWP is configured; and

switching to an initial BWP if the default BWP is not configured.
The UE as claimed in Claim 62, performing the HD-FDD transmission with radio resource management further comprising:

when the HD-FDD transmission is switched to the UL mode, suspending the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

resuming the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The UE as claimed in Claim 62, performing the HD-FDD transmission with radio resource management further comprising:

when the HD-FDD transmission is switched to the UL mode, stopping the BWP inactivity timer at the beginning or end of the DL-to-UL GP; and

restarting the BWP inactivity timer at the beginning or end of the UL-to-DL GP.
The UE as claimed in Claim 52, performing the HD-FDD transmission with radio resource management further comprising:

if the BWP switching is triggered at a timing insufficient to complete the BWP switching before mode switching, ignoring the request; and

if the request is triggered by a BWP inactivity timer, restarting the BWP inactivity timer.
The UE as claimed in Claim 52, performing the HD-FDD transmission with radio resource management further comprising:

if the BWP switching is requested at a timing insufficient to complete the BWP switching before mode switching, executing the BWP switching and the mode switching; and

if the UE is in a RRC connected state, notifying the network about the BWP switching before execution.