Patent Publication Number: US-2021195680-A1

Title: Terminal apparatus, communication method, and computer-readable storage medium in wireless communication system in which terminal apparatus performs communication in standby state

Description:
CROSS-REFERENCE TO RELATED APPLICATION(S) 
     This application is a continuation of International Patent Application No. PCT/JP2019/030334 filed on Aug. 1, 2019, which claims priority to and the benefit of Japanese Patent Application No. 2018-175781 filed on Sep. 20, 2018, the entire disclosures of which are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The present invention relates to a terminal apparatus, a communication method, and a computer-readable storage medium, and in particular relates to a control technique for when the terminal apparatus in a standby state transmits a signal. 
     Description of the Related Art 
     In 3GPP, NR (New Radio) has been standardized as the fifth-generation wireless communication scheme (see Non-patent Document 1). An NR terminal apparatus may change to not only two states, namely RRC_CONNECTED and RRC_IDLE that an LTE (Long Term Evolution) terminal apparatus may enter, but also to an RRC_INACTIVE state. Here, RRC_CONNECTED refers to a state of being connected to and being in communication with a base station apparatus, and RRC_INACTIVE and RRC_IDLE refer to standby states. Note that the RRC_INACTIVE state is a state where context information regarding a terminal apparatus for the terminal apparatus to communicate with a core network is held by a base station apparatus to which the terminal apparatus was connected until the terminal apparatus changed to the RRC_INACTIVE state (a base station apparatus to which the terminal apparatus was connected for the last time), and the RRC_IDLE state is a state where such information is not held by the base station apparatus. 
     Non-patent Document 2 describes that consideration is given to a terminal apparatus in the RRC_INACTIVE state to transmit data, and that an MA (Multiple Access) signature is allocated to the terminal apparatus for such data transmission. The MA signature may be information for specifying a data transmission pattern inherent to the terminal apparatus, such as a time/frequency wireless resource block, MCS (Modulation and Coding Scheme), DMRS (Demodulate Reference Signal) for specifying the terminal apparatus, and an interleaving pattern. The terminal apparatus transmits data using the MA signature, and the base station apparatus can separate and identify the data transmitted from the terminal apparatus using this MA signature. 
     CITATION LIST 
     Patent Literature 
     
         
         NPL 1: 3GPP TS 38.300, V15.2.0, June 2018 
         NPL 2: 3GPP written contributions, RP-171043 
       
    
     As described above, the terminal apparatus in the RRC_INACTIVE state can transmit data without changing to the RRC_CONNECTED state, by using the MA signature. At this time, the terminal apparatus can establish time synchronization with a base station apparatus to which the data is to be transmitted, and then transmit the data, but the terminal apparatus can also transmit data without establishing time synchronization. 
     SUMMARY OF THE INVENTION 
     The present invention provides a technique that makes it possible to perform flexible control as to whether or not to establish time synchronization when a terminal apparatus in a standby state transmits a data signal. 
     A terminal apparatus according to one mode of the present invention is a terminal apparatus that is operable in a plurality of states that include a first state where connection with a base station apparatus is established and a second state where connection with the base station apparatus is not established but the base station apparatus holds information regarding the terminal apparatus, wherein the terminal apparatus receives, from the base station apparatus, information regarding whether or not to establish time synchronization when a signal is to be transmitted to the base station apparatus in the second state, determines, based on the information, whether or not to establish time synchronization when a signal is to be transmitted to the base station apparatus in the second state, and transmits a signal to the base station in the second mode with executing processing for establishing time synchronization with the base station apparatus if it is determined that time synchronization is to be established, and without executing the processing if it is determined that time synchronization is not to be established. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain principles of the invention. 
         FIG. 1  is a diagram showing a configuration example of a wireless communication system. 
         FIG. 2  is a diagram showing an exemplary hardware configuration of an apparatus. 
         FIG. 3  is a diagram showing an exemplary functional configuration of a terminal apparatus. 
         FIG. 4  is a diagram showing an exemplary functional configuration of a base station apparatus. 
         FIG. 5  is a diagram showing an example of the flow of processing that is executed in the wireless communication system. 
         FIG. 6  is a diagram showing an example of the flow of processing that is executed by a terminal apparatus. 
     
    
    
     DESCRIPTION OF THE EMBODIMENTS 
     Hereinafter, embodiments will be described in detail with reference to the attached drawings. Note that the following embodiment does not limit the scope of the claimed invention, and all of the combinations of characteristics described in the embodiment are not necessarily essential to the invention. Two or more out of a plurality of characteristics described in the embodiment may be suitably combined. In addition, the same reference numerals are given to the same or similar configurations, and redundant description thereof is omitted. 
     Configuration of Wireless Communication System 
       FIG. 1  shows a configuration example of a wireless communication system according to an embodiment of the present invention. This wireless communication system is configured by including a base station apparatus  101  and a terminal apparatus  102 , for example. Note that  FIG. 1  shows one base station apparatus and one terminal apparatus in order to simplify the description, but there may be a large number of base station apparatuses and a large number of terminal apparatuses, as in a general cellular communication system. Note that an example will be described below in which NR, which complies with the fifth-generation wireless communication scheme, is used, but there is no limitation thereto. The following discussion can apply to, for example, fifth-generation or later cellular communication systems and any other systems that include a terminal apparatus (communication apparatus) that can transmit/receive certain data in a standby state such as an RRC_INACTIVE state stipulated for NR. Accordingly, the base station apparatus  101  may be any base station apparatus that can communicate with not only a terminal apparatus with which connection has been established, but also a terminal apparatus with which connection has not been established but that can perform certain data communication. In addition, the terminal apparatus  102  is configured to be operable in a first state where connection with the base station apparatus is established and a second state where connection with the base station apparatus is not established but it is possible to perform a certain amount of data communication with the base station apparatus. 
     The base station apparatus  101  is a base station apparatus (gNB) that is operable in accordance with NR, for example. The base station apparatus  101  forms one or more cells/beams, and provides a communication service to the terminal apparatus  102  in the range of the cells/beams. The terminal apparatus  102  is a terminal apparatus that is operable in accordance with NR, and can communicate with NR base station apparatus. 
     The terminal apparatus  102  can obtain an MA signature from the base station apparatus  101  and use the MA signature for performing communication with the base station apparatus  101 , for example. Note that the MA signature is predetermined information that enables data communication at least in the RRC_INACTIVE state, and other information may also be used instead of or in addition to the MA signature. Note that the MA signature can also be used in the RRC_CONNECTED state, for example. After receiving the MA signature, the terminal apparatus  102  may change to the RRC_INACTIVE state in accordance with an RRCRelease message accompanied by suspendConfig being received from the base station apparatus  101 , for example. 
     The terminal apparatus  102  can transmit a data signal to the base station apparatus  101  while maintaining the RRC_INACTIVE state. At this time, for example, the terminal apparatus  102  can transmit physical random access channel (PRACH) to the base station apparatus  101  and receive a timing advance (TA) command from the base station apparatus  101  so as to establish time synchronization with the base station apparatus  101 , and then transmit an uplink signal. Specifically, the terminal apparatus  102  calculates the relative time difference between the leading time of a downlink wireless frame and the leading time of an uplink wireless frame, using the TA command received from the base station apparatus  101 , and determines a timing for transmitting an uplink data signal based on the calculation result. As a result of the terminal apparatus  102  establishing time synchronization with the base station apparatus  101  and transmitting a data signal in this manner, the base station apparatus  101  can extract the data signal with a relatively low processing load. In this case, it should be noted that the terminal apparatus  102  can transmit the data signal while maintaining the RRC_INACTIVE state, without changing to the RRC_CONNECTED state. In addition, the terminal apparatus  102  can transmit a data signal to the base station apparatus  101  without establishing time synchronization with the base station apparatus  101 . Accordingly, the above-described processing for establishing time synchronization between the terminal apparatus  102  and the base station apparatus  101 , the processing being related to the TA command, is not necessary, and thus it is possible to suppress a delay in transmission of the data signal although the processing load of the base station apparatus  101  is relatively large. Therefore, for example, a terminal apparatus  102  for which a low delay is requested (asynchronously) transmits a data signal without establishing time synchronization, so as to suppress the delay amount, and it is envisioned that another terminal apparatus  102  performs operations of establishing time synchronization and transmitting a data signal, so as to suppress the processing load, for example. 
     According to this embodiment, in order to perform such flexible operations, the base station apparatus  101  may notify the terminal apparatus  102  of information regarding whether the terminal apparatus  102  is to establish time synchronization and then transmit a data signal, or asynchronously transmit a data signal. 
     The information that is notified can be instruction information indicating that time synchronization is to be established or is not to be established, for example. In this case, in accordance with this instruction information, the terminal apparatus  102  establishes time synchronization and then transmits a data signal if instructed to establish time synchronization, and the terminal apparatus  102  asynchronously transmits a data signal if instructed to not establish time synchronization. For example, the base station apparatus  101  can instruct a terminal apparatus  102  that performs communication for a service for which a low delay is requested, or the like, to asynchronously transmit a data signal, and instruct another terminal apparatus  102  to establish time synchronization and then transmit a data signal. Accordingly, the base station apparatus  101  can flexibly perform setting on whether or not to establish time synchronization, for each terminal apparatus  102 . Note that the instruction information may be notified, for example, only when an instruction to not establish time synchronization is given. Specifically, a configuration is adopted in which, if the instruction information is not notified, the terminal apparatus  102  establishes time synchronization and then transmits a data signal, and, only if the instruction information is notified, the terminal apparatus  102  asynchronously transmits a data signal. Accordingly, notification that time synchronization is to be established is performed implicitly by the instruction information not being transmitted. Accordingly, the amount of instruction information that is transmitted decreases, and thus it is possible to reduce the signaling overhead. 
     Note that the terminal apparatus  102  in the RRC_CONNECTED state is in a state of receiving the TA command from the base station apparatus  101 , and thus does not asynchronously transmit a signal. In addition, the terminal apparatus  102  in the RRC_IDLE state changes to the RRC_CONNECTED state when transmitting a data signal, and thus does not asynchronously transmit a signal, either. Accordingly, both synchronized communication and asynchronous communication here are related to communication that is performed by the terminal apparatus  102  in the RRC_INACTIVE state (standby state). 
     Note that information that is notified to the terminal apparatus  102  by the base station apparatus  101  may be condition information indicating a condition under which the terminal apparatus  102  is to establish time synchronization, and, in this case, a configuration can be adopted in which, when the condition under which time synchronization is to be established is satisfied, the terminal apparatus  102  establishes time synchronization and then transmits a data signal, and, while the condition is not satisfied, the terminal apparatus  102  asynchronously transmits a data signal. Accordingly, the condition information in this case is information indicating a condition for determining whether or not the terminal apparatus  102  is to establish time synchronization and then transmit a data signal. This condition may be that, for example, data that is to be transmitted arise in communication for which a low delay is requested such as real-time communication. 
     Note that, even when asynchronous communication is performed, it is requested that variation in the timing of the terminal apparatus  102  transmitting a data signal be within a certain time range, using, as a reference, a state where time synchronization is established. This is because, if the variation is significantly large, it is difficult for the base station apparatus  101  to detect the signal. Therefore, an event for which it is envisioned that the timing of the terminal apparatus  102  transmitting a data signal is out of the certain time range may be set as the above-described condition. 
     For example, it is indicated that, as the condition information, time synchronization is to be established when the change amount of received power of a predetermined signal such as an SS (Synchronization Signal) or an informing signal (Physical Broadcast Channel, PBCH) from the base station apparatus  101  exceeds a predetermined value. Note that this change amount may be a change amount of an average power value per unit time, or may be a change amount of an instantaneous power value. When the received power value of the signal from the base station apparatus  101  has significantly changed, it is envisioned that the distance (of the transmission path, for example) between the base station apparatus  101  and the terminal apparatus  102  has significantly changed, and thus this condition can be provided. When the change amount of the received power of the predetermined signal has significantly changed, it is envisioned that the time until the signal transmitted from the terminal apparatus  102  reaches the base station apparatus  101  will significantly change, and thus, when this condition is satisfied, the terminal apparatus  102  may establish time synchronization and then asynchronously resume communication. 
     In addition, for example, it can be indicated, as the condition information, that time synchronization is to be established when a time length elapsed from when the terminal apparatus  102  established time synchronization and transmitted a data signal exceeds a predetermined length. This is because, when the terminal apparatus  102  establishes time synchronization, time synchronization is established accurately at this point, but it is envisioned that the synchronization is lost gradually with the lapse of time. Note that it suffices for time synchronization to be reestablished based on determination as to whether or not synchronization is lost, when data that is to be transmitted arises and the data is transmitted, and it is not necessary to reestablish time synchronization when the time length from when time synchronization was established and data transmission was performed reaches a predetermined length. 
     In addition, it may be indicated that, as condition information, time synchronization is to be established, in accordance with the terminal apparatus  102  having been moved over cells. Also in this case, there are cases where, due to the terminal apparatus  102  having been moved over cells, the propagation distance of a signal that is transmitted from the terminal apparatus  102  and reaches the base station apparatus  101  changes a larger amount than envisioned, and thus, if this condition is satisfied, the terminal apparatus  102  may establish time synchronization and then resume asynchronous communication. 
     Note that a plurality of conditions may be set, or only one condition may be set. For example, at least one of the above-described condition related to the change amount of the received power of the predetermined signal from the base station apparatus  101 , condition related to a time elapsed from when time synchronization was established and a data signal was transmitted, and condition related to whether or not the terminal apparatus  102  has been moved over cells can be notified as condition information to the terminal apparatus  102 . Note that at least some of these pieces of condition information may be set for the terminal apparatus  102  in advance, and, in this case, the terminal apparatus  102  may independently determine whether or not to establish time synchronization irrespective of notification from the base station apparatus  101 . 
     Note that the base station apparatus  101  can separate/extract a signal component from a received signal that includes the signal component and is asynchronously transmitted from the terminal apparatus  102 , using the MA signature set for the terminal apparatus  102 . Therefore, a configuration may also be adopted in which the above-described information is not notified to a terminal apparatus  102  for which no MA signature is set, based on the assumption that the terminal apparatus  102  is to establish time synchronization, and the above-described information is notified only to a terminal apparatus  102  for which an MA signature has been set. Accordingly, it is not necessary to notify a terminal apparatus  102  for which no MA signature is set, that time synchronization is to be established at the time of signal transmission, and thus it is possible to prevent unnecessary signaling from being performed. In addition, this information may also be included in a message for setting an MA signature and transmitted to the terminal apparatus  102 . Accordingly, it is possible to efficiently notify the terminal apparatus  102  for which an MA signature is set, that time synchronization is to be or not to be established. In addition, the base station apparatus  101  may also notify the terminal apparatus  102  of the above-described information, for example, using a message (the RRCRelease message that includes suspendConfig) for changing the state of the terminal apparatus  102  to the RRC_INACTIVE state. Accordingly, unnecessary notification of the above-described information is not performed to the terminal apparatus  102  that does not change to the RRC_INACTIVE state, and, in addition, it is possible to perform setting on whether or not to establish time synchronization, individually for each terminal apparatus  102  that changes to the RRC_INACTIVE state. In addition, the base station apparatus  101  may also perform notification of the above-described information, for example, using any message that enables information to be transmitted to the terminal apparatus  102  in the RRC_INACTIVE state, or using any message that is transmitted to the terminal apparatus  102  while the state is the RRC_CONNECTED state. Accordingly, notification of the above-described information may also be performed using a message for performing notification of an MA signature or a message for changing the state to the RRC_INACTIVE state, or using any other message (signal). 
     Apparatus Configuration 
     Next, an exemplary hardware configuration of the base station apparatus  101  or the terminal apparatus  102  that execute the above-described processing will be described with reference to  FIG. 2 . These apparatuses are each constituted by a processor  201 , a ROM  202 , a RAM  203 , a storage apparatus  204 , and a communication circuit  205 , for example. The processor  201  is a computer configured by including one or more processing circuits such as a general-purpose CPU (central computation apparatus) and an ASIC (Application-Specific Integrated Circuit), and executes overall processing of each apparatus or the above-described processing as a result of reading out a program stored in the ROM  202  or the storage apparatus  204  and executing the program. The ROM  202  is a read-only memory that stores information such as programs related to processing that is executed by the apparatuses and various parameters. The RAM  203  is a random access memory that functions as a work space when the processor  201  executes a program, and stores temporary information. The storage apparatus  204  is constituted by a removable external storage apparatus, for example. The communication circuit  205  is constituted by a circuit for wired communication or wireless communication, for example. The base station apparatus  101  is configured by including an antenna and a baseband circuit, RF circuit, and the like for NR, as the communication circuit  205  for performing communication with the terminal apparatus  102 . In addition, the communication circuit  205  of the base station apparatus  101  may also include, for example, a circuit for performing (wired or wireless) communication with another base station apparatus or network node. In addition, the communication circuit  205  of the terminal apparatus  102  is configured by including an antenna and a baseband circuit, RF circuit, and the like for NR. In addition, the terminal apparatus  102  may include the communication circuit  205  for performing wireless LAN communication or communication that complies with another communication standard. Note that,  FIG. 2  illustrates one communication circuit  205 , but each apparatus may include a plurality of communication circuits. 
       FIG. 3  shows a schematic example of the functional configuration of the terminal apparatus  102 . The terminal apparatus  102  includes a communication unit  301 , a control unit  302 , and an information holding unit  303 , for example. The communication unit  301  performs communication with a base station apparatus. Note that the communication unit  301  is operable in one of three states, namely RRC_CONNECTED, RRC_INACTIVE, and RRC_IDLE under control of the base station apparatus, and is configured to be able to transmit/receive data to/from the base station apparatus that is connected thereto in the RRC_CONNECTED state. In addition, also in the RRC_INACTIVE state, the communication unit  301  can transmit a small amount of data to the base station apparatus, using the MA signature held in the information holding unit  303  to be described later. The control unit  302  can control the communication unit  301  so as to execute various types of processing of the terminal apparatus  102  such as those described above. Specifically, the control unit  302  controls the communication unit  301 , for example, in accordance with instruction information received from the base station apparatus  101 , so as to establish time synchronization with the base station apparatus  101  and transmit a data signal to the base station apparatus  101  if an instruction to establish time synchronization is received, and so as to asynchronously transmit a data signal to the base station apparatus  101  while maintaining the RRC_INACTIVE state if an instruction to not establish time synchronization is received. The control unit  302  can also determine whether or not to establish time synchronization and then transmit a signal, for example, in accordance with information regarding a condition notified from the base station apparatus  101  and held in the information holding unit  303 , and control the communication unit  301 , in accordance with the determination, so as to establish time synchronization and then transmit a data signal to the base station apparatus  101  or asynchronously transmit a data signal while maintaining the RRC_INACTIVE state. The information holding unit  303  holds the MA signature set by the base station apparatus in the RRC_CONNECTED state, for example. In addition, the information holding unit  303  can hold information regarding the condition that is used for determining whether or not to establish time synchronization, the information having been notified from the base station apparatus  101 . 
       FIG. 4  shows a schematic example of the functional configuration of the base station apparatus  101 . The base station apparatus  101  includes a communication unit  401 , a control unit  402 , and an information management unit  403 , for example. The communication unit  401  communicates with the terminal apparatus  102  and another base station apparatus. Note that a communication unit for performing wireless communication with the terminal apparatus  102  and a communication unit for performing communication with another base station apparatus may be prepared separately, but, for example, in a case where communication with another base station apparatus is executed in accordance with the NR standard, only one communication unit  401  may be prepared. 
     The control unit  402  may control the communication unit  401  so as to execute various types of processing of the base station apparatus such as those described above. For example, the control unit  402  controls the information management unit  403  so as to set an MA signature for the terminal apparatus  102  and hold the MA signature. In addition, a configuration may also be adopted in which the control unit  402  determines, for each terminal apparatus  102 , whether or not to establish time synchronization, based on a condition for determining whether or not to establish time synchronization for information indicating a service for which terminal apparatuses  102  managed by the information management unit  403  are performing communication, for example, and controls the communication unit  401  so as to transmit an instruction that is based on the determination. In addition, the control unit  402  may control the communication unit  401 , for example, so as to notify the terminal apparatus  102  of the above-described condition related to the change amount of the wireless quality such as received power of a predetermined signal from the base station apparatus  101  or condition related to the lapsed time from when time synchronization was established and data was transmitted. Note that, when notification of a condition is performed, a common condition may be notified to a plurality of terminal apparatuses  102 , or a condition different for each terminal apparatus  102  may be notified, for example, based on classification such as the category of the terminal apparatus  102  (stipulated by 3GPP, for example). The information management unit  403  may manage, for example, the MA signature set for each terminal apparatus  102  and a condition for determining whether or not to establish time synchronization for information indicating a service for which the terminal apparatus  102  is performing communication, and the like. The information management unit  403  can also hold information such as a measurement value that is used for this determination. 
     Flow of Processing 
       FIG. 5  shows an example of the flow of processing that is executed by the wireless communication system according to this embodiment.  FIG. 5  shows an example in which the base station apparatus  101  transmits, respectively to two terminal apparatuses  102 , an instruction to establish time synchronization and then transmit a signal and an instruction to asynchronously transmit a signal. Note that the two terminal apparatuses  102  (a terminal apparatus A and a terminal apparatus B) are in a state where connection is established with the base station apparatus  101  (the RRC_CONNECTED state)(step S 501 ). At this time, for example, MA signatures are separately set for these terminal apparatuses  102  in the RRC_CONNECTED state (not illustrated). The base station apparatus  101  transmits the RRCRelease message that includes suspendConfig for changing the terminal apparatus A and the terminal apparatus B from this state to the RRC_INACTIVE state. At this time, the base station apparatus  101  transmits, to the terminal apparatus A, the RRCRelease message that includes instruction information instructing that time synchronization is to be established and then uplink data is to be transmitted (step S 502 ). Accordingly, when transmitting uplink data, the terminal apparatus A performs settings for establishing time synchronization, and then changes to the RRC_INACTIVE state (step S 503 ). On the other hand, the base station apparatus  101  transmits, to the terminal apparatus B, the RRCRelease message that includes instruction information instructing that uplink data is to be asynchronously transmitted without establishing time synchronization (step S 504 ). Accordingly, the terminal apparatus B performs settings for asynchronously transmitting uplink data, and then changes to the RRC_INACTIVE state (step S 505 ). Note that, in the example in  FIG. 5 , instruction information instructing to or not to establish time synchronization is notified in the RRCRelease message, but the base station apparatus  101  may also perform notification of this instruction information, for example, in a message for setting an MA signature (not illustrated). 
     Thereafter, if data that is to be transmitted arises (step S 506 ), the terminal apparatus A transmits PRACH to the base station apparatus  101  (step S 507 ), receives the TA command (step S 508 ), and establishes time synchronization with the base station apparatus  101 . The terminal apparatus A then transmits a data signal at a timing determined as a result of time synchronization being established in steps S 507  and S 508  (step S 509 ). On the other hand, when data that is to be transmitted arises (step S 510 ), the terminal apparatus B asynchronously transmits a data signal without transmitting PRACH and receiving the TA command (step S 511 ). Note that “asynchronous” here refers to accurate time synchronization having not been established, and the terminal apparatus B can transmit a data signal to the base station apparatus  101  within a predetermined time range based on wireless resources specified based on the MA signature, for example. Accordingly, the base station apparatus  101  does not need to perform processing for detecting a signal outside of the predetermined time range that is determined based on the MA signature, for example. 
     In this manner, the base station apparatus  101  can flexibly perform settings for synchronization/asynchronization for each terminal apparatus  102 , for example, by performing an instruction to asynchronously transmit a signal, when a delay time allowable for a service that is executed by the terminal apparatus  102  is shorter than or equal to a predetermined value, and by performing an instruction to establish time synchronization and then transmit a signal, when the delay time exceeds the predetermined value. 
     Note that the base station apparatus  101  may also perform notification of condition information such as that described above instead of an instruction signal. In this case, the terminal apparatus  102  can determine whether or not to establish time synchronization at the time of signal transmission, based on whether or not the situation of the terminal apparatus  102  satisfies the notified condition. As described above, the condition can be, for example, the condition related to the change amount of the wireless quality of the received power or the like of a predetermined signal transmitted from the base station apparatus  101 , or the condition related to a lapsed time from when time synchronization was established and a signal was transmitted.  FIG. 6  shows an example of the flow of processing when these conditions are used. Note that only one of these conditions, for example, the condition related to a lapsed time may also be used, or another condition may also be used alternatively or additionally. For example, a configuration may also be adopted in which the terminal apparatus  102  extracts the identifier of a cell (e.g., Physical Cell ID or PCI) from a received synchronization signal or informing signal, and when the identifier changes, the terminal apparatus  102  establishes time synchronization and transmit a signal. 
     Note that  FIG. 6  shows an example in which, when the lapsed time has reached the predetermined time and the change amount of the received power of the predetermined signal exceeds the predetermined value, the terminal apparatus  102  makes a determination to establish time synchronization, but these may also be dealt with in parallel. Specifically, when the lapsed time reaches the predetermined time, the terminal apparatus  102  may make a determination to establish time synchronization even when the change amount of the received power of the predetermined signal does not exceed the predetermined value, and, when the change amount of the received power of the predetermined signal exceeds the predetermined value, the terminal apparatus  102  may make a determination to establish time synchronization even when the lapsed time has not reached the predetermined time. In this manner, when a plurality of conditions are used, unless two or more of the conditions are not satisfied at the same time, a determination may also be made to asynchronously transmit a signal, or, when only one of these condition is satisfied, a determination may be made to establish time synchronization and then transmit a signal. 
     In  FIG. 6 , the terminal apparatus  102  obtains, as condition information, information regarding the expiration value of a timer and a predetermined value for the change amount of the received power of the predetermined signal (for example, synchronization signal/informing signal), from the base station apparatus  101 , and stores the information in advance. The terminal apparatus  102  then measures and holds the value of the received power of the predetermined signal from the base station apparatus  101  at a time point when the terminal apparatus  102  changes to the RRC_INACTIVE state (or during a predetermined period before and after the time point) (step S 601 ), for example. The terminal apparatus  102  starts the timer in this state (step S 602 ). Thereafter, when the terminal apparatus  102  detects that data that is to be transmitted has arisen (step S 603 ), the terminal apparatus  102  determines whether or not the data is to be transmitted in the RRC_INACTIVE state (step S 604 ). If it is determined that the data is not to be transmitted in the RRC_INACTIVE state (in other words, the data is to be transmitted after the state has changed to the RRC_CONNECTED state) (NO in step S 604 ), the terminal apparatus  102  changes to the RRC_CONNECTED state, transmits a data signal that includes the data (step S 605 ), and ends the processing in  FIG. 6 . In the RRC_CONNECTED state, the terminal apparatus  102  establishes time synchronization and then transmits the data. Note that, if the terminal apparatus  102  changes to the RRC_INACTIVE state again after transmitting the data signal in step S 605 , the terminal apparatus  102  may resume the processing in  FIG. 6 . 
     On the other hand, if it is determined that the data is to be transmitted in the RRC_INACTIVE state (YES in step S 604 ), the terminal apparatus  102  determines whether or not the timer started in step S 602  has reached the expiration value notified from the base station apparatus  101  (step S 606 ). If the timer has not expired (NO in step S 606 ), the terminal apparatus  102 , which is still in the RRC_INACTIVE state, transmits a data signal that includes the data arose in step S 603  without establishing time synchronization (step S 607 ). On the other hand, if the timer has expired (YES in step S 606 ), the terminal apparatus  102  measures the received power of the predetermined signal from the base station apparatus  101  (step S 608 ). The terminal apparatus  102  then specifies, as a change amount, the value of the difference between the measurement value and the value held in step S 601 , and determines whether or not the specified change amount exceeds the predetermined value for the change amount notified from the base station apparatus  101  (step S 609 ). If the change amount of the received power does not exceed the predetermined value (NO in step S 609 ), the terminal apparatus  102  transmits a data signal that includes the data that arose in step S 603  while maintaining the RRC_INACTIVE state (step S 607 ). Note that, after this, the timer is in an expired state, and thus the terminal apparatus  102  may determine whether or not the change amount of the received power exceeds the predetermined value, every time data that is to be transmitted arises. Note that there is no limitation thereto, and, if it is determined in step S 609  that the change amount of the received power does not exceed the predetermined value, the terminal apparatus  102  may reset the timer. If the change amount of the received power exceeds the predetermined value (YES in step S 609 ), the terminal apparatus  102  establishes time synchronization with the base station apparatus  101 , and then transmits a data signal while maintaining the RRC_INACTIVE state (step S 610 ). Note that the terminal apparatus  102  may establish time synchronization and then transmit a data signal, only in accordance with the timer having expired, or only in accordance with the change amount of the received power exceeding the predetermined value. The terminal apparatus  102  updates the value of the received power of the predetermined signal obtained in step S 601  (or updated in the previous step S 611 ), to the value measured in step S 608  in accordance with time synchronization having been established (step S 611 ), and resets the timer (step S 612 ). The procedure is then returned to step S 603 . 
     Note that the above example is illustrated in which, after it is detected that the timer has expired, a determination is performed as to whether or not the change amount of the received power of the predetermined signal exceeds the predetermined value, but such a determination order may be reversed. Accordingly, a configuration may also be adopted in which, after it is determined that the change amount of the received power of the predetermined signal has exceeded the predetermined value, the timer value is referenced. In this manner, the processing in  FIG. 6  is only exemplary, and the processing order may be changed, or the processing may be partially omitted or processing (not illustrated) may be added. 
     In addition, as described above, the terminal apparatus  102  can make a determination to establish time synchronization, based only on the value of the timer (irrespective of the change amount of the received power), but, even when such a determination is made, the terminal apparatus  102  can update the measurement value of the received power that is held, to the measurement value of the received power at a timepoint when time synchronization is established and a data signal is transmitted. Similarly, if it is determined that time synchronization is to be established based only on the change amount of the received power, when the timer value is used as a condition, the terminal apparatus  102  may reset the timer at a timepoint when time synchronization is established and a data signal is transmitted. In addition, for example, when the terminal apparatus  102  established time synchronization and transmitted a data signal in accordance with being moved to a cell different from a cell that has changed to the RRC_INACTIVE state, the terminal apparatus  102  can reset the timer and update the measurement value of the received power that is held. Note that, when a determination is made as to whether or not time synchronization can be established based on movement over cells, the terminal apparatus  102  can update information regarding PCI, so as to hold PCI at the timepoint when time synchronization is established and a data signal is transmitted. In addition, even in a case where the terminal apparatus  102  established time synchronization and transmitted a data signal due to a cause other than a change in PCI, the terminal apparatus  102  can update the value of PCI to the value of PCI of the serving cell at the time of transmission of the data signal. 
     As described above, as a result of setting, for the terminal apparatus  102 , a condition under which time synchronization is to be established and a data signal is to be transmitted, the base station apparatus  101  can flexibly perform setting on whether or not to establish time synchronization in accordance with the situation of the terminal apparatus  102 . Note that, for example, only a terminal apparatus  102  for which the allowable delay amount is small may be notified of a condition by the base station apparatus  101 , and, regarding a terminal apparatus  102  to which this condition is not to be notified, the base station apparatus  101  can perform settings so as to establish time synchronization and transmit a data signal, irrespective of the condition. Accordingly, regarding at least some of the terminal apparatuses  102 , for example, a terminal apparatus  102  for which a delay is not strictly requested, and the like, it is possible to reduce the processing load of the base station apparatus  101  as a result of establishing time synchronization irrespective of a condition. 
     According to the present invention, it is possible to perform flexible control as to whether or not to establish time synchronization when a terminal apparatus in a standby state transmits a data signal. 
     While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.