KR20120103668A - Method for determining downlink time reference - Google Patents

Abstract

The present invention provides a method for determining a downlink time reference, wherein the terminal uses the downlink primary element carrier as a time reference and based on the time reference, the uplink data is transmitted by a time advance (TA). Determining the absolute time to transmit. The present invention provides a method for determining a downlink time criterion, which includes a method for a downlink element carrier or a downlink element carrier corresponding to an uplink element carrier or an uplink element carrier for which a terminal performs random access. Determine an absolute time for transmitting uplink data by time advance (TA), still based on a time base and other downlink element carriers located in the same frequency band as the corresponding downlink element carrier. It is included. In the present invention, the base station transmits downlink data to the terminal simply and easily using a plurality of downlink element carriers, and when some downlink element carriers use a remote radio head (RRH) or a repeater, Solve setup problems.

Description

How to determine downlink time criteria {METHOD FOR DETERMINING DOWNLINK TIME REFERENCE}

TECHNICAL FIELD The present invention relates to the field of wireless communications, and in particular, to a method of determining a downlink time criterion.

In Long Term Evolution (LTE) systems, user equipment (UE) must acquire uplink synchronization and downlink synchronization with the base station before transmitting the uplink data to the base station. If the UE fails to acquire downlink synchronization with the cell, a process similar to cell search should be performed. As shown in Figure 1, the downlink time delay is obtained through downlink synchronization. Uplink synchronization is obtained through a random access procedure (as well as Time Advance (TA) up to transmission time, which includes uplink and downlink transmission time delays). The primary use of a TA is to allow the UE to determine the data transmission time. In the LTE system, since there is only one carrier in a cell, a time (i.e., T2 time in FIG. 1) is determined by combining TAs based on the downlink of this carrier as a time reference, so that T1 / T2 / Since T3 is all absolute time and both the base station and the UE are time aligned, if the UE wants the base station to receive data at T3, the UE must send data to the base station at T2 time, and from the base station's point of view, the UE The time T2 is equal to the time T1 of the base station. The random access process involves both collisions and no collisions. The uplink and downlink carriers performing the collision-free random access procedure may be matching carriers of the same frequency or matching carriers of different frequencies. The uplink and downlink carriers performing the random access procedure of collision must be matched carriers of the same frequency. When performing a collision-free random access procedure, the terminal transmits a random access preamble to the base station (the component carrier transmitting the random access preamble is an uplink carrier that directly performs a random access), and the base station transmits a random access response to the terminal. The component carrier to which the base station transmits the random access response is a downlink carrier which performs the random access procedure. When executing the random access procedure of the collision, as shown in Figure 2, the terminal and the base station (E-UTRAN Node B, eNB) in addition to the two message interactions, the following two messages, namely the terminal The collision should be resolved by including the interaction of the scheduling transmission message sent to the base station and the conflict resolution message returned by the base station to the terminal.

In order to provide higher data rates to mobile users, enhanced long-term evolution (LTE-Advanced, LTE-A) proposes carrier aggregation technology, which aims to provide user equipment with corresponding capabilities. In order to improve the peak speed of the UE by providing a larger bandwidth. In LTE, the maximum downlink transmission bandwidth supported by the system is 20 MHz, and the carrier aggregation supports more than 20 MHz bandwidth by integrating two or more component carriers (CCs), and down to 100 MHz or more. It can support link transmission bandwidth.

The component carrier may use a predetermined frequency band for LTE, or may use a bandwidth professionally added for LTE-A. In the present situation where the frequency spectrum is tense, carrier aggregation cannot be assigned to an operator because there is always a contiguous element carrier in the frequency domain, so that carrier aggregation is dependent on whether each element carrier is contiguous in the frequency domain. It can be distinguished by continuous carrier aggregation. Carrier aggregation can be divided into carrier aggregation of a single band and carrier aggregation of multiple frequency bands by whether each element carrier is in the same frequency band. So-called single band carrier aggregation refers to that all element carriers participating in the carrier integration are all in the same frequency band, which may be either continuous carrier aggregation or discontinuous carrier integration; So-called multi-frequency band carrier aggregation refers to element carriers participating in carrier integration coming from different frequency bands. An LTE UE can only transmit and receive data on an element carrier that is compatible with LTE, but with an LTE-A UE equipped with carrier aggregation capability (the UE in the following for convenience of description is this type of UE unless otherwise specified). Can transmit and receive data on multiple element carriers at the same time. Corresponding transmission and reception equipment of the UE is a set of baseband equipment, one single frequency band, bandwidth is 20MHz or more, or multiple sets of baseband equipment, multiple frequency bands, each bandwidth band 20MHz It may be

In an LTE-A system, a UE may communicate with a source base station through a plurality of element carriers (for example, CC1 and CC2) simultaneously after entering a connected state, wherein CC1 is a primary element carrier (Primary). Component Carrier (PCC), and for example, CC2 is a Secondary Component Carrier (SCC). Terminals use non-access stratum (NAS) information (e.g., enhanced cell global identity (ECGI) and tracking area identity (TAI), etc.) via the primary element carrier. Acquiring, if a radio link failure (RLF) situation appears in the downlink primary element carrier, the UE should perform a radio resource control (RRC) reconfiguration procedure. After the UE connects to the network from the idle state and enters the connected state, the element carrier performing the connection is the primary element carrier. When the UE is in the connected state, the network completes the switching process of the PCC through RRC reconfiguration or in-cell switching, or the network side designates a primary element carrier in the process of notifying the UE to switch.

In addition, in order to improve the coverage of the base station, for some downlink carriers, for example, CC2, if the base station uses a remote radio head (RRH) technology or has a signal repeater, the base station simultaneously operates with CC1. Although data is transmitted to the UE on CC2, the time when these two carrier data arrive at the UE is different, as shown in FIG. If both uplink and downlink CC2 use RRH or signal repeater, the base station only configures downlink CC2 for the UE, so the same problem exists. Since the uplink data transmission time delays of CC1 and CC2 coincide, it is reasonable to maintain one TA, but since the TA is one time relative amount, how to transmit uplink data by this relative amount of time is absolute. There is currently no solution for determining the time.

The present invention provides a method for determining a downlink time reference so that a base station transmits downlink data to a terminal using multiple downlink element carriers, and when some downlink element carriers use an RRH or repeater, It aims to solve configuration problems.

In order to solve the above problem, the present invention provides a method for determining a downlink time reference,

The terminal includes a downlink primary element carrier as a time reference and determines an absolute time for transmitting uplink data by time advance based on the time reference.

In this method,

When a change in downlink main element carrier occurs, the terminal is time based on the new downlink main element carrier.

In this method,

A radio link failure situation occurs on the downlink primary element carrier, causing the terminal to initiate a radio link control reconfiguration process to cause a change in the downlink primary element carrier so that the terminal is time-based on the new downlink primary element carrier. Included.

In this method,

The base station performs reconfiguration through a radio link control process so that another downlink element carrier other than the downlink main element carrier is a downlink main element carrier, and the terminal uses a new downlink main element carrier as a time reference. Included.

In this method,

When the uplink synchronization of the terminal is released and uplink data arrives, the terminal again initiates a random access procedure to cause a change in the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. It is included.

In this method,

Under the situation that the uplink synchronization of the terminal is released and downlink data arrives and the base station allocates a dedicated preamble for the terminal, the terminal starts the random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. And causing the terminal to change the downlink main element carrier, based on the current downlink main element carrier.

In this method,

After the terminal undergoes base station switching and on the component carrier with random access resources provided by the target base station, the terminal initiates a random access procedure to cause a change in the downlink primary component carrier. A time reference is included for the downlink main element carrier to be used.

In order to solve the above problem, the present invention also provides a method for determining the downlink time reference,

A downlink element carrier on which the terminal performs random access, or a downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; It is still based on the time reference and determining the absolute time of transmitting the uplink data by time advance based on this time reference.

In this method,

After completing the new random access procedure, a change occurs in the downlink element carrier that executes the random access procedure, such that the terminal is time-based on the new downlink element carrier that executes the random access procedure.

In this method,

A downlink element carrier or uplink element executing a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; A time reference is still included for the downlink element carrier corresponding to the carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier.

In this method,

When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier corresponding to the uplink element carrier or the downlink element carrier executing the random access, Or still based on a time-based other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier.

In this method,

When the uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal starts the random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. Downlink element carriers for performing random access, or downlink element carriers corresponding to the uplink element carriers, or other downlink element carriers located in the same frequency band as the downlink element carriers corresponding to the uplink element carriers. It still includes time base.

In this method,

The terminal proceeds with the base station switching, and initiates a random access procedure on the component carrier having a random access resource provided by the target base station, so that the terminal and the downlink element carrier or uplink element carrier to perform the random access; A still time reference is included for the corresponding downlink element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier.

In this method,

After the downlink element carrier executing the random access procedure is deleted or deactivated, the terminal is time based on the downlink primary element carrier.

In this method,

Time-based downlink element carriers corresponding to the uplink element carriers of the terminal, and after the base station deletes the downlink element carriers, the terminal times other downlink element carriers corresponding to the uplink element carriers. Reference is also made to a time reference or other downlink element carriers located in the same frequency band as the downlink element carriers.

In order to solve the above problem, the present invention also provides a terminal, the terminal,

Determine an absolute time for transmitting uplink data by time advance based on the downlink primary element carrier and based on the time reference; or

The downlink element carrier performing the random access, or the downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still timed. It is set to determine the absolute time of transmitting uplink data by time advance based on this time reference.

The terminal is also

When the terminal is configured to determine an absolute time for transmitting uplink data by time advance based on the downlink primary element carrier and based on the time reference,

After a change in downlink main element carrier, the terminal is based on a new downlink main element carrier; or

A radio link failure situation occurs on the downlink main element carrier such that the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier, such that the terminal is based on the new downlink main element carrier; or

The base station performs reconfiguration through a radio link control process so that another downlink element carrier other than the downlink main element carrier is a downlink main element carrier, and the terminal is based on a new downlink main element carrier; or

When the uplink synchronization of the terminal is released and uplink data arrives, the terminal again initiates a random access procedure to cause a change in the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. do or; or

Under the situation that the uplink synchronization of the terminal is released and downlink data arrives and the base station allocates a dedicated preamble for the terminal, the terminal performs a random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. After starting and causing a change in the downlink main element carrier, the terminal is based on a current downlink main element carrier; or

After the terminal undergoes base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station to cause a change in the downlink primary element carrier, the terminal uses the downlink used by the target base station. It is set to be based on the primary element carrier.

The terminal is also

A downlink element carrier on which the terminal performs random access, or a downlink element carrier corresponding to an uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to an uplink element carrier. Is still time-based and is set to determine an absolute time for transmitting uplink data by time advance based on this time reference,

After completing the new random access procedure, a change occurs in the downlink element carrier that executes the random access procedure, such that the terminal is based on a new downlink element carrier that executes the random access procedure; or

A downlink element carrier or uplink element executing a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; Still a time reference to the downlink element carrier corresponding to the carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or

When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier corresponding to the uplink element carrier or the downlink element carrier executing the random access, Or is still time based on other downlink element carriers located in the same frequency band as the downlink element carriers corresponding to the uplink element carriers; or

When the uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal starts the random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. Downlink element carriers for performing random access, or downlink element carriers corresponding to the uplink element carriers, or other downlink element carriers located in the same frequency band as the downlink element carriers corresponding to the uplink element carriers. Still based on time; or

The terminal proceeds with the base station switching, and initiates a random access procedure on the component carrier having a random access resource provided by the target base station, so that the terminal and the downlink element carrier or uplink element carrier to perform the random access; Still a time reference to the corresponding downlink element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or

After the downlink element carrier executing the random access procedure is deleted or deactivated, the terminal is time-based on the downlink primary element carrier; or

Time-based downlink element carriers corresponding to the uplink element carriers of the terminal, and after the base station deletes the downlink element carriers, the terminal times other downlink element carriers corresponding to the uplink element carriers. It is set to be a time reference or to other downlink element carriers located in the same frequency band as the downlink element carrier.

In the present invention, the base station simply and easily transmits downlink data to a terminal using a plurality of downlink element carriers, and solves a problem of setting downlink time reference when some downlink element carriers use an RRH or repeater.

1 is a time advance (TA) diagram of a terminal in an LTE system.
2 is a random access procedure diagram based on collision.
3 is a time delay diagram of transmission and reception after introducing a downlink RRH or repeater into an LTE-A system.
4 is an application situation diagram in Embodiments 1 to 5 of the present invention;
5 and 6 are diagrams in which the UE determines data transmission time according to downlink time reference and TA in Embodiments 1 to 5 of the present invention.
7 is an application situation diagram in Embodiment 6 of the present invention;
8 is a diagram in which a UE determines data transmission time according to a downlink time criterion and a TA in Embodiment 6 of the present invention;

Two solutions to this problem are presented.

Method 1: Determine an absolute time for the terminal to transmit uplink data by time advance based on the downlink primary element carrier and based on the time reference. After a change in the downlink main element carrier, the terminal is time-based on the new downlink main element carrier.

Method 2: The downlink element carrier where the terminal performs random access, or the downlink element carrier corresponding to the uplink element carrier, or other downlink located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier The component carrier is still based on the time reference, and based on this time reference, the absolute time of transmitting uplink data by time advance is determined. The downlink component carrier performing the random access is the component carrier to which the base station transmits the random access response message.

After the completion of the new random access procedure, a change occurs in the downlink element carrier that executes the random access procedure, so that the terminal transmits uplink data based on a new downlink element carrier that performs the random access procedure. Determine the time.

A downlink element carrier or uplink element executing a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; The downlink element carrier corresponding to the carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still based on time.

When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier corresponding to the uplink element carrier or the downlink element carrier executing the random access, Or another downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier.

When the uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal starts the random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. Thus, the downlink element carrier performing the random connection, or the downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier. Is still based on time.

The terminal proceeds with the base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station, so that the terminal corresponds to a downlink element carrier or downlink element carrier that performs random access. The link element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still based on time.

After the downlink element carrier performing the random access procedure is deleted or deactivated, the terminal is time-based on the downlink primary element carrier.

The terminal is based on the downlink component carrier corresponding to the uplink component carrier, and after the base station deletes the downlink component carrier, the terminal is based on the other downlink component carrier corresponding to the uplink component carrier. Or other downlink element carriers located in the same frequency band as the downlink element carriers are still based on time.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that, in a non-conflicting situation, the embodiments of the present application and the features in the embodiments may be combined with each other.

Example 1, Example 2, Example 3, and Example 4 use Method 1, and Example 5 and Example 6 use Method 2. In an embodiment, when the uplink or downlink data arrives when the uplink synchronization is released, the UE should again initiate a random access procedure. In the following examples, the frequency bands to which each element carrier belongs may be the same or may be different.

Example  One

A radio link failure situation occurs on the downlink main element carrier such that the terminal initiates a radio link control reconfiguration process, causing a change in the downlink main element carrier, so that the terminal references the new downlink main element carrier as a time reference.

As shown in FIG. 4, the UE resides in CC1, initiates an RRC connection configuration request on the CC1 according to a higher layer service request (including a random access procedure), and acquires a TA after completing the random access procedure. CC1 is the PCC, after which the UE enters the connected state.

If the network side configures CC2 for the UE according to the service request and performs carrier aggregation, the downlink (DL) CC2 includes a signal repeater (if using RRH technology, subsequent processing is the same). The component carriers currently used by the UE are DL CC1, DL CC2, and uplink (UL) CC1 and UL CC2, UL CC1 and DL CC1 are PCC, and UL CC2 and DL CC2 are SCC. The UE has two receivers, and is responsible for receiving DL CC1 and DL CC2, respectively.

As shown in FIG. 5, if the DL PCC (ie, DL CC1) is a time reference, and the TA is a time difference between T2 and T1 (ie, TA1), the UE determines an absolute time for transmitting data by TA1. Data transmitted from the base station to the UE through the DL CC1 reaches the UE at time T2, data transmitted to the UE through the DL CC2 reaches the UE at time T3, and the UE transmits data of the base station at the time T2 and T3 respectively. Receive.

If the DL CC1 signal changes quickly and badly at any one time and an RLF occurs in the DL CC1, the UE triggers the RRC reconfiguration. Since the signal of the DL CC1 is bad, the result of the UE performing the cell selection is CC2, the CC2 initiates the random access, after completing the random access, the UE enters the connected state and the CC2 is the PCC. At this time, DL PCC (ie, DL CC2) is used as a time reference, and if TA is a time difference between T3 and T1 (ie, TA2), the UE determines an absolute time for transmitting data by TA2.

Example  2

The base station performs reconfiguration through a radio link control process so that another downlink element carrier other than the downlink main element carrier is a downlink main element carrier, and the terminal uses a new downlink main element carrier as a time reference.

4, the description will be continued. The UE initiates RRC connection through CC1 in the LTE-A system and enters the connected state, and the component carriers currently used by the UE are DL CC1, DL CC2 and UL CC1 and ULCC2, and UL CC1 and DL CC1 are PCC, The UL CC2 and the DL CC2 are SCCs, which are based on a DL PCC (ie, DL CC1) as a time reference, and determine an absolute time for transmitting data by TA1. The UE has two receivers, and is responsible for receiving DL CC1 and DL CC2, respectively.

Since the signal of the DL CC1 is bad, the base station converts the DL CC2 to the DL PCC through RRC reconfiguration, but does not delete the DL CC1, and the DL PCC is converted to the DL CC2 since the UE and the DL CC2 maintain downlink synchronization all the time. Later (ie, after the UE responds to the base station with the reconfiguration complete message), the TA changes to the time difference between T3 and T1 (ie TA2), and the UE determines the absolute time for transmitting data by TA2. Data transmitted from the base station to the UE through the DL CC1 reaches the UE at time T2, data transmitted to the UE through the DL CC2 reaches the UE at time T3, and the UE transmits data of the base station at the time T2 and T3 respectively. Received, as shown in FIG.

Example  3

When the uplink synchronization of the terminal is released and uplink data arrives, the terminal starts the random access procedure again to change the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. . Under the situation that the uplink synchronization of the terminal is released and the downlink data arrives and the base station allocates the dedicated preamble for the terminal, the terminal starts the random access procedure again on the element carrier to which the dedicated preamble allocated by the base station belongs. After causing a change in the link main element carrier, the terminal is based on the current downlink main element carrier.

4, the description will be continued. The current UE is connected in the LTE-A system, and the component carriers currently used by the UE are DL CC1, DL CC2 and UL CC1 and ULCC2, UL CC2 and DL CC2 are PCC, and UL CC1 and DL CC1 are SCC to be. The UE has two receivers, and is responsible for receiving DL CC1 and DL CC2, respectively.

When the uplink data is released when the UE is deactivated uplink synchronization, the random access procedure should be started again. The random access procedure is based on collision, and the UE selects the UL CC1 and the DL CC1 to perform random access. Since the access procedure is initiated and the current DL PCC (i.e., DL CC2) is used as a time reference, the UE transmits a random access preamble to the base station at the time T3. , As shown in FIG. 6.

If the downlink data arrives and the base station assigns a dedicated preamble on CC1 to the UE, the UE should start the random access procedure again, which is a non-conflicting process. . Since the UE initiates a random access procedure on CC1 and based on the current DL PCC (ie DL CC2) as time reference, the UE transmits a random access preamble to the base station at time T3, and the time delays of UL CC1 and UL CC2 are equal. Therefore, the acquired TA is TA2, as shown in FIG.

Example  4

When the terminal proceeds with the base station switching, the terminal initiates a random access procedure on a component carrier having a random access resource provided by the target base station to cause a change in the downlink primary component carrier, and then the terminal uses the downlink primary used by the target base station. The urea carrier is based on time.

4, the description will be continued. If the UE is currently connected in the LTE-A system, the source base station switches the UE to CC1 and transmits a switching request message to the target base station, and the target base station configures CC1 and CC2 to the UE to proceed with carrier aggregation. Provide all random access resources on CC1. The UE initiates a random access procedure at the target base station on CC1, and after completing the random access procedure, acquires the TA of the target base station, where CC1 is the PCC, and then the UE connects to the target base station. The element carriers currently used by the UE are DL CC1, DL CC2, UL CC1, and UL CC2, UL CC1 and DL CC1 are PCC, and UL CC2 and DL CC2 are SCC. The UE has two receivers, and is responsible for receiving DL CC1 and DL CC2, respectively.

As shown in FIG. 5, if the DL PCC (ie, DL CC1) is a time reference, and the TA is a time difference between T2 and T1 (ie, TA1), the UE determines an absolute time for transmitting data by TA1. Data transmitted from the base station to the UE through the DL CC1 reaches the UE at time T2, data transmitted to the UE through the DL CC2 reaches the UE at time T3, and the UE transmits data of the base station at the time T2 and T3 respectively. Receive.

Example  5

4, the description will be continued. The UE initiates RRC connection through CC1 in the LTE-A system and enters the connected state, and the component carriers currently used by the UE are DL CC1, DL CC2 and UL CC1 and ULCC2, and UL CC1 and DL CC1 are PCC, The UL CC2 and the DL CC2 are SCCs. The downlink CC (that is, the DL CC1) performing random access is determined based on time, and the absolute time of transmitting data is determined by TA1. The UE has two receivers, and is responsible for receiving DL CC1 and DL CC2, respectively. CC1 and CC2 belong to frequency band 5.

Since the signal of the DL CC1 is bad, when the RLF occurs in the DL CC1, the terminal initiates a radio link control reconfiguration process, the base station converts the DL CC2 to DL PCC through the RRC reconfiguration, but does not delete the DL CC1, The uplink / downlink correspondence is modified to UL CC1 and DL CC2, and since the DL PCC is converted to DL CC2 because the UE and DL CC1 maintain downlink synchronization all the time (that is, the UE responds to the base station with a reconfiguration complete message). After that), the UE still bases on the downlink CC (i.e., DL CC1) executing the random access, and the UE still determines the absolute time of transmitting data by TA1. As shown in FIG. In the above process, if the base station deletes or deactivates CC1, the UE bases downlink main element carrier DL PCC (ie DL CC2) on a time basis, and the TA is also adjusted to TA2 correspondingly.

When uplink data arrives when the UE has deactivated uplink synchronization, the random access procedure should be started again. The random access procedure is based on collision, and the UE randomly selects UL CC1 and DL CC2. Since the downlink CC (i.e., DL CC2) that initiates the access process and executes the random process should be based on time, the UE transmits a random access preamble to the base station at time T3, the acquired TA is TA2, and the UE is TA2. By confirming the absolute time for transmitting data by, as shown in FIG.

If the downlink data arrives and the base station assigns a dedicated preamble on CC1 to the UE, the UE should start the random access procedure again, which is a non-conflicting process. . Since the UE initiates a random access procedure on UL CC1 and based on the current downlink CC (ie DL CC2) as a time reference, the UE transmits a random access preamble to the base station at time T3, and the acquired TA is TA2, and the UE The absolute time of transmitting data by TA2 is still determined, as shown in FIG.

Example  6

7, the CC1 and CC3 belong to the frequency band 5, and the CC2 belongs to the frequency band 1. As shown in FIG. The UE initiates RRC connection through CC1 in the LTE-A system and enters the connected state, and the base station configures CC3 and DL CC2 for the UE by the service request, among which DL CC2 uses RRH. The element carriers currently used by the UE are DL CC1, DL CC2, DL CC3 and UL CC1, UL CC3, among which, UL CC1 and DL CC1 are PCC, DL CC2, DL CC3 and UL CC3 are SCC, and UL CC The downlink CC (DL CC1 or DL CC3) corresponding to the time basis, or the other downlink CC (ie DL CC3 or DL CC1) of the same frequency band as the downlink CC as the time reference, TA1 by Determine the absolute time to send data. Since the downlink time delays of CC1 and CC3 coincide, the UE only needs to have two receivers responsible for the reception of DL CC1 and DL CC3 and the reception of DL CC2, respectively.

Since the signal of the DL CC1 is bad, the base station initiates a radio link control reconfiguration process, and the base station converts the DL CC2 to the DL PCC through RRC reconfiguration but does not delete the DL CC1. At this time, the uplink / downlink correspondence is modified to UL CC1 and DL CC2. After the DL PCC has been converted to DL CC2 (ie, after the UE has responded to the base station with the reconfiguration complete message), the UE is still time-based on the downlink CC (ie DL CC1 or DL CC3) corresponding to the UL CC. Still determines the absolute time of transmitting data by TA1. As shown in FIG. If the DL CC1 is deleted, the downlink CC (for example, DL CC3) of the same frequency band as the DL CC1 may be set as a time reference.

When uplink data arrives when the UE has deactivated uplink synchronization, the random access procedure should be started again. The random access procedure is based on collision, and the UE selects UL CC3 and DL CC3 to randomize the random access procedure. Initiating the access process, the UE is based on the downlink CC (ie DL CC1 or DL CC3) corresponding to the UE CC as a time reference, the UE transmits a random access preamble to the base station at time T2, the acquired TA is TA1, The UE still determines the absolute time of transmitting data by TA1, as shown in FIG.

If the downlink data arrives and the base station assigns a dedicated preamble on CC3 to the UE, the UE should start the random access procedure again, which is a non-conflicting process. . The UE initiates a random access procedure on the UL CC3, the UE bases its time on the downlink CC (ie DL CC1 or DL CC3) corresponding to the UC CC, the UE transmits the random access preamble to the base station at T2 time, The acquired TA is TA1, and the UE still determines the absolute time of transmitting data by TA1, as shown in FIG.

In the above procedure, if the base station deleted CC1, the UE still bases other downlink component carriers on the same frequency band as CC1, and the TA used is TA1.

In the present invention also provides a terminal, the terminal,

Determine an absolute time for transmitting uplink data by time advance based on the downlink primary element carrier and based on the time reference; or

The downlink element carrier performing the random access, or the downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still timed. It is set to determine the absolute time of transmitting uplink data by time advance based on this time reference.

The terminal is also

When the terminal is configured to determine an absolute time for transmitting uplink data by time advance based on the downlink primary element carrier and based on that time reference,

After a change in downlink main element carrier, the terminal is based on a new downlink main element carrier; or

A radio link failure situation occurs on the downlink main element carrier such that the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier, such that the terminal is based on the new downlink main element carrier; or

The base station performs reconfiguration through a radio link control process so that another downlink element carrier other than the downlink main element carrier is a downlink main element carrier, and the terminal is based on a new downlink main element carrier; or

When the uplink synchronization of the terminal is released and uplink data arrives, the terminal again initiates a random access procedure to cause a change in the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. do or; or

Under the situation that the uplink synchronization of the terminal is released and downlink data arrives and the base station allocates a dedicated preamble for the terminal, the terminal performs a random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. After starting and causing a change in the downlink main element carrier, the terminal is based on a current downlink main element carrier; or

After the terminal undergoes base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station to cause a change in the downlink primary element carrier, the terminal uses the downlink primary used by the target base station. It is set to make the element carrier time based.

The terminal is also

A downlink element carrier on which the terminal performs random access, or a downlink element carrier corresponding to an uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to an uplink element carrier. Is still time-based and is set to determine an absolute time for transmitting uplink data by time advance based on this time reference,

After completing the new random access procedure, a change occurs in the downlink element carrier that executes the random access procedure, such that the terminal is based on a new downlink element carrier that executes the random access procedure; or

A downlink element carrier or uplink element executing a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; Still a time reference to the downlink element carrier corresponding to the carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or

When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier corresponding to the uplink element carrier or the downlink element carrier executing the random access, Or is still time based on other downlink element carriers located in the same frequency band as the downlink element carriers corresponding to the uplink element carriers; or

When the uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal starts the random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. Downlink element carriers for performing random access, or downlink element carriers corresponding to the uplink element carriers, or other downlink element carriers located in the same frequency band as the downlink element carriers corresponding to the uplink element carriers. Still based on time; or

The terminal proceeds with the base station switching and initiates a random access procedure on an element carrier with random access resources provided by the target base station, so that the terminal corresponds to a downlink element carrier or uplink element carrier that performs random access. A time-based downlink element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or

After the downlink element carrier executing the random access procedure is deleted or deactivated, the terminal is time-based on the downlink primary element carrier; or

Time-based downlink element carriers corresponding to the uplink element carriers of the terminal, and after the base station deletes the downlink element carriers, the terminal times other downlink element carriers corresponding to the uplink element carriers. It is set to be a time reference or to other downlink element carriers located in the same frequency band as the downlink element carrier.

While the invention has been shown and described with respect to specific embodiments thereof, the invention is not limited to only the embodiments described above, and those of ordinary skill in the art to which the invention pertains may find the invention described in the claims below Various changes can be made without departing from the spirit of the technical idea of the invention.

Persons skilled in the art can complete all or some of the steps of the method through instructing related hardware through a program, which program may be stored in a computer-readable medium, for example, a ROM, a driver or a disk. It should be understood that there is. All or some of the steps of the above embodiments may optionally be implemented using one or more integrated circuits. Correspondingly, each module / unit in the above embodiment may be implemented through a hardware form or a software form. The present invention is not limited to any specific type of combination of hardware and software.

[Industrial applicability]

In the present invention, the base station simply and easily transmits downlink data to the terminal using a plurality of downlink element carriers, and solves the problem of setting downlink time reference when some downlink element carriers use RRHs or repeaters.

Claims (18)

A method of determining a downlink time criterion,
Determining an absolute time at which a terminal transmits uplink data by time advance based on the downlink primary element carrier as a time reference and based on the time reference.
And determining a downlink time reference. The method of claim 1,
In this method,
And when the change occurs in the downlink main element carrier, the terminal further comprises a new downlink main element carrier as a time reference. The method according to claim 1 or 2,
In this method,
A radio link failure situation occurs on the downlink primary element carrier, such that the terminal initiates a radio link control reconfiguration process, causing a change in the downlink primary element carrier, such that the terminal is time-based on the new downlink primary element carrier. The method for determining a downlink time reference, characterized in that it further comprises. The method according to claim 1 or 2,
In this method,
The base station performs reconfiguration through a radio link control process so that another downlink element carrier other than the downlink main element carrier is a downlink main element carrier, and the terminal uses a new downlink main element carrier as a time reference. Further comprising a downlink time criterion. The method according to claim 1 or 2,
In this method,
When the uplink synchronization of the terminal is released and uplink data arrives, the terminal again initiates a random access procedure to cause a change in the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. The method for determining a downlink time reference, characterized in that it further comprises. The method according to claim 1 or 2,
In this method,
Under the situation that the uplink synchronization of the terminal is released and downlink data arrives and the base station allocates a dedicated preamble for the terminal, the terminal performs a random access procedure again on an element carrier to which the dedicated preamble allocated by the base station belongs. And initiating a change in downlink main element carrier, the terminal further comprising the current downlink main element carrier as a time reference. The method according to claim 1 or 2,
In this method,
After the terminal undergoes base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station to cause a change in the downlink primary element carrier, the terminal uses the downlink used by the target base station. And based on the primary element carrier as a time reference. A method of determining a downlink time criterion,
A downlink element carrier on which the terminal performs random access, or a downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; It is still a time reference and based on this time reference is used to determine the absolute time of transmitting uplink data by time advance.
And determining a downlink time reference. The method of claim 8,
In this method,
After completing the new random access procedure, a change occurs in the downlink component carrier for executing the random access procedure, and the terminal further includes time-based on the new downlink component carrier for performing the random access procedure. Determining a downlink time criterion. The method of claim 8,
In this method,
A downlink element carrier on which the terminal executes a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; Or still based on a downlink element carrier corresponding to the uplink element carrier or another downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier. Determining a downlink time criterion. The method of claim 8,
In this method,
When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier or the downlink element corresponding to the uplink element carrier performs the random access. Further comprising still a time reference to the carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier. The method of claim 8,
In this method,
When uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal randomly accesses again on an element carrier to which the dedicated preamble allocated by the base station belongs. A downlink element carrier for performing the random access, or a downlink element carrier corresponding to an uplink element carrier, or other downlink located in the same frequency band as the downlink element carrier corresponding to an uplink element carrier. And further comprising a component carrier as a time reference. The method of claim 8,
In this method,
The terminal proceeds with the base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station, so that the terminal corresponds to a downlink element carrier or uplink element carrier performing the random access. Determining a downlink time criterion, further comprising a time-based still being a downlink element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier. How to. The method of claim 8,
In this method,
And after the downlink element carrier executing the random access procedure is deleted or deactivated, the terminal further comprises a downlink primary element carrier as a time reference. The method of claim 8,
In this method,
The terminal times the downlink component carrier corresponding to the uplink component carrier, and after the base station deletes the downlink component carrier, the terminal times the other downlink component carrier corresponding to the uplink component carrier. And further comprising a time reference as a reference or other downlink element carriers located in the same frequency band as the downlink element carriers. In the terminal,
The terminal,
Determine an absolute time for transmitting uplink data by time advance with the downlink primary element carrier as a time reference and based on the time reference; or
The downlink element carrier performing the random access, or the downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still timed. And determine an absolute time for transmitting uplink data by time advance based on this time reference.
Terminal, characterized in that. The method of claim 16,
The terminal,
When the terminal is configured to determine an absolute time for transmitting uplink data by time advance based on the downlink primary element carrier and based on the time reference,
When a change occurs in the downlink main element carrier, the terminal is based on a new downlink main element carrier; or
A radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier so that the terminal is time-based on the new downlink main element carrier. ; or
If the base station performs reconfiguration through a radio link control process and makes another downlink element carrier other than the downlink main element carrier as the downlink main element carrier, the terminal uses the new downlink main element carrier as a time reference; or
When the uplink synchronization of the terminal is released and uplink data arrives, the terminal again initiates a random access procedure to cause a change in the downlink main element carrier, and then the terminal uses the current downlink main element carrier as a time reference. Or; or
Under the situation that the uplink synchronization of the terminal is released but downlink data arrives and the base station allocates a dedicated preamble for the terminal, the terminal randomly accesses again on an element carrier to which the dedicated preamble allocated by the base station belongs. After initiating a change in the downlink main element carrier, the terminal is based on the current downlink main element carrier as time reference; or
After the terminal undergoes base station switching and initiates a random access procedure on an element carrier having a random access resource provided by the target base station to cause a change in the downlink primary element carrier, the terminal uses the downlink primary used by the target base station. And characterized in that it is set to be based on the element carrier on a time basis. The method of claim 16,
The terminal,
A downlink element carrier on which the terminal performs random access, or a downlink element carrier corresponding to an uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to an uplink element carrier. Is still time-based and is set to determine an absolute time for transmitting uplink data by time advance based on this time reference,
After completing the new random access procedure, a change occurs in the downlink element carrier that executes the random access procedure, such that the terminal is based on a new downlink element carrier that executes the random access procedure; or
A downlink element carrier on which the terminal executes a random access after a radio link failure situation occurs on the downlink main element carrier and the terminal initiates a radio link control reconfiguration process to cause a change in the downlink main element carrier; Or still a time reference to the downlink element carrier corresponding to the uplink element carrier, or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or
When the uplink synchronization of the terminal is released and the uplink data arrives, the terminal starts the random access procedure again, and the downlink element carrier or the downlink element corresponding to the uplink element carrier performs the random access. The carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier is still based on time; or
When uplink synchronization of the terminal is released and downlink data arrives, the base station allocates a dedicated preamble for the terminal, and the terminal randomly accesses again on an element carrier to which the dedicated preamble allocated by the base station belongs. A downlink element carrier for performing the random access, or a downlink element carrier corresponding to an uplink element carrier, or other downlink located in the same frequency band as the downlink element carrier corresponding to an uplink element carrier. The element carrier is still based on time; or
The terminal proceeds with the base station switching and initiates a random access procedure on an element carrier with random access resources provided by the target base station, so that the terminal corresponds to a downlink element carrier or uplink element carrier that performs random access. A time-based downlink element carrier or other downlink element carrier located in the same frequency band as the downlink element carrier corresponding to the uplink element carrier; or
After the downlink element carrier executing the random access procedure is deleted or deactivated, the terminal is time-based on the downlink primary element carrier; or
The terminal times the downlink component carrier corresponding to the uplink component carrier, and after the base station deletes the downlink component carrier, the terminal times the other downlink component carrier corresponding to the uplink component carrier. And further set to still be time reference based on other downlink element carriers that are referenced or located in the same frequency band as the downlink element carriers.

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