U.S. patent application number 15/339515 was filed with the patent office on 2017-02-16 for optimized serving dual cell change.
The applicant listed for this patent is INTERDIGITAL PATENT HOLDINGS, INC.. Invention is credited to Paul Marinier, Diana Pani, Benoit Pelletier.
Application Number | 20170048779 15/339515 |
Document ID | / |
Family ID | 41066099 |
Filed Date | 2017-02-16 |
United States Patent
Application |
20170048779 |
Kind Code |
A1 |
Pani; Diana ; et
al. |
February 16, 2017 |
OPTIMIZED SERVING DUAL CELL CHANGE
Abstract
A method and apparatus for implementing serving cell change in a
multi-cell wireless transmit receive unit (WTRU) are disclosed.
Serving cell information is received and stored by the WTRU to
preconfigure a primary and secondary serving cell of an added cell
to an active set. At least one of the preconfigured primary and
secondary serving cells are monitored for a handover indication.
Serving cell change is to the primary and secondary serving cells
is performed using the preconfigured serving cell information upon
receipt of a handover indication.
Inventors: |
Pani; Diana; (Montreal,
CA) ; Marinier; Paul; (Brossard, CA) ;
Pelletier; Benoit; (Roxboro, CA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
INTERDIGITAL PATENT HOLDINGS, INC. |
Wilmington |
DE |
US |
|
|
Family ID: |
41066099 |
Appl. No.: |
15/339515 |
Filed: |
October 31, 2016 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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12487969 |
Jun 19, 2009 |
9532288 |
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15339515 |
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61074006 |
Jun 19, 2008 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H04W 36/28 20130101;
H04W 72/0406 20130101; H04W 72/0453 20130101; H04W 36/08
20130101 |
International
Class: |
H04W 36/28 20060101
H04W036/28; H04W 72/04 20060101 H04W072/04; H04W 36/08 20060101
H04W036/08 |
Claims
1.-14. (canceled)
15. A method implemented by a wireless transmit receive unit
(WTRU), the method comprising: transmitting information on a
primary uplink frequency on a serving cell; receiving information
on a primary downlink frequency on the serving cell and at least
one secondary downlink frequency on a secondary serving cell;
receiving target cell pre-configuration information, wherein the
target cell pre-configuration information includes high speed
dedicated shared channel (HS-DSCH) configuration information for
the at least one secondary downlink frequency; storing the target
cell pre-configuration information; transmitting a measurement
report with event 1D; and monitoring control signals in a target
cell.
16. The method of claim 15, wherein the control signals are
monitored on a carrier frequency having the same frequency as the
primary downlink frequency.
17. The method of claim 15, further comprising: transmitting
information on at least one secondary uplink frequency on the
secondary uplink serving cell
18. The method of claim 15, wherein the control signals are
received over a high speed shared control channel (HS-SCCH).
19. The method of claim 18, further comprising: performing a
serving cell change using the target cell per-configuration
information on a condition that a target cell HS-SCCH order is
received on the HS-SCCH of the target cell.
20. The method of claim 18, further comprising: performing a
secondary serving cell change on a condition that a target cell
HS-SCCH order is received on the HS-SCCH of the target cell.
21. The method of claim 15, wherein the serving cell and the
secondary serving cell are HS-DSCH cells and wherein the target
cell pre-configuration information includes a HS-DSCH radio network
transaction identifier (H-RNTI).
22. The method of claim 15, wherein the target cell
pre-configuration information is associated with the primary
downlink frequency of the serving cell and at least one secondary
downlink frequency of the secondary serving cell.
23. A wireless transmit receive unit (WTRU) comprising: circuitry
configured to transmit information on a primary uplink frequency on
a serving cell; circuitry configured to receive information on a
primary downlink frequency on the serving cell and at least one
secondary downlink frequency on a secondary serving cell; circuitry
configured to receive target cell pre-configuration information,
wherein the target cell pre-configuration information includes high
speed dedicated shared channel (HS-DSCH) configuration information
for the at least one secondary downlink frequency; circuitry
configured to store the target cell pre-configuration information;
circuitry configured to transmit a measurement report with event
1D; and circuitry configured to monitor control signals in a target
cell.
24. The WTRU of claim 23, wherein the control signals are monitored
on a carrier frequency having the same frequency as the primary
downlink frequency.
25. The WTRU of claim 23, further comprising: circuitry configured
to transmit information on at least one secondary uplink frequency
on the secondary uplink serving cell
26. The WTRU of claim 23, wherein the control signals are received
over a high speed shared control channel (HS-SCCH).
27. The WTRU of claim 26, further comprising: circuitry configured
to perform a serving cell change using the target cell
pre-configuration information on a condition that a target cell
HS-SCCH order is received on the HS-SCCH of the target cell.
28. The WTRU of claim 26, further comprising: circuitry configured
to perform a secondary serving cell change on a condition that a
target cell HS-SCCH order is received on the HS-SCCH of the target
cell.
29. The WTRU of claim 23, wherein the serving cell and the
secondary serving cell are HS-DSCH cells, wherein the target cell
pre-configuration information includes a HS-DSCH radio network
transaction identifier (H-RNTI), and wherein the target cell
pre-configuration information is associated with the primary
downlink frequency of the serving cell and at least one secondary
downlink frequency of the secondary serving cell.
30. A method implemented by a wireless transmit/receive unit
(WTRU), the method comprising: transmitting a 1A or a 1C
measurement report; receiving target cell pre-configuration
information, wherein the target cell pre-configuration information
includes enhanced dedicated channel (E-DCH) configuration
information for a secondary uplink frequency, and wherein the E-DCH
configuration information includes E-DCH relative grant channel
(E-RGCH) information; and transmitting a 1D measurement report.
31. The method of claim 30, wherein the target cell
pre-configuration information includes a high-speed downlink shared
channel (HS-DSCH) radio network transaction identifier
(H-RNTI).
32. The method of claim 30, further comprising: transmitting
information on a primary uplink frequency on a serving cell and a
secondary uplink frequency on a secondary serving cell; and
receiving information on a primary downlink frequency on the
serving cell and a secondary downlink frequency on the secondary
serving cell.
33. The method of claim 32, further comprising: storing the target
cell pre-configuration information; and monitoring control signals
on the target cell, the serving cell, and the secondary serving
cell.
34. The method of claim 32, further comprising: receiving a high
speed shared control channel (HS-SCCH), order to activate or
deactivate the secondary uplink frequency and the secondary
downlink frequency.
35. A wireless transmit/receive unit (WTRU) comprising: circuitry
configured to transmit a 1A or a 1C measurement report; circuitry
configured to receive target cell pre-configuration information
wherein the target cell pre-configuration information includes
enhanced dedicated channel (E-DCH) configuration information for a
secondary uplink frequency, and wherein the E-DCH configuration
information includes E-DCH relative grant channel (E-RGCH)
information; and circuitry configured to transmit a 1D measurement
report.
36. The WTRU of claim 35, wherein the target cell pre-configuration
information includes a high-speed downlink shared channel (HS-DSCH)
radio network transaction identifier, (H-RNTI).
37. The WTRU of claim 35, further comprising: circuitry configured
to transmit information on a primary uplink frequency on a serving
cell and a secondary uplink frequency on a secondary serving cell;
and circuitry configured to receive information on a primary
downlink frequency on the serving cell and a secondary downlink
frequency on the secondary serving cell.
38. The WTRU of claim 23, further comprising: circuitry configured
to store the target cell pre-configuration information; and
circuitry configured to monitor control signals on the target cell,
the serving cell, and the secondary serving cell.
39. The WTRU of claim 23, further comprising: circuitry configured
to receive a high speed shared control channel (HS-SCCH) order to
activate or deactivate the secondary uplink frequency and the
secondary downlink frequency.
Description
CROSS REFERENCE TO RELATED APPLICATION(S)
[0001] This application is a continuation of U.S. patent
application Ser. No. 12/487,969, filed Jun. 19, 2009, which claims
the benefit of U.S. Provisional Patent Application Ser. No.
61/074,006, filed Jun. 19, 2008; both of which are incorporated by
reference as if fully set forth.
FIELD OF INVENTION
[0002] This application is related to wireless communications.
BACKGROUND
[0003] As part of the on-going evolution of the third Generation
Partnership Project (3GPP) Wideband Code Division Multiple Access
(WCDMA) standard, Dual-Cell High-Speed Downlink Packet Access
(HSDPA) (DC-HSDPA) has been approved in 3GPP. Dual-cell HSDPA is a
natural evolution of High Speed Packet Access (HSPA) which allows
the use of a second HSPA carrier (i.e. two 5 MHz downlink carriers)
to create a bigger downlink data pipe.
[0004] The DC-HSDPA operation is backward compatible with Release
7, 6, and 5, and Release 99 devices through seamless interoperation
between single-carrier and dual-carrier coverage areas. Dual-cell
operation provides both throughput increase and latency reduction.
Most importantly, more wireless transmit receive units (WTRUs) have
access to higher data rates, especially in poor radio conditions
where techniques such as Multiple Input Multiple Output (MIMO) are
not used. In terms of system performance, Dual-Cell HSDPA offers
efficient load balancing across carriers and some capacity
gain.
[0005] The agreed dual-cell operation in Release 8 of the 3GPP
standard only applies to the downlink, with the uplink (UL)
transmission restricted to a single cell, i.e., carrier.
Furthermore, the following additional restrictions have been
imposed: the two downlink cells belong to the same Node-Band are on
adjacent carriers (and by extension the carriers are in the same
frequency band); two carriers operating in the dual-cell have the
same time reference and their downlinks are synchronized; and the
two downlink cells cover the same geographical area(sector).
Accordingly, a dual-cell capable WTRU is configured to receive two
downlink carriers (an anchor carrier and a supplementary carrier),
and to transmit one uplink anchor carrier. The downlink anchor
carrier is matched with the uplink anchor carrier.
[0006] Additionally, inter-frequency handovers can be used to
change anchor carriers within a Node-B.
[0007] A Dual Cell HSDPA WTRU may be configured to perform normal
mobility procedures. An important aspect of HSDPA and enhanced
dedicated channel (E-DCH) mobility is the serving cell change
(handover). Handover is the process in which a WTRU switches from
one cell to another without service interruption. Soft handover
refers to a feature where a WTRU is simultaneously connected to two
or more cells (or cell sectors) during a call. If the sectors are
from the same physical cell site (a sectorized site), it is
referred to as softer handover.
[0008] In HSDPA, the handover procedure does not allow for soft
handover or softer handover. The high-speed shared channels are
monitored by the WTRU in a single cell, which is called the serving
HS-DSCH cell. During handover, the WTRU switches to a new serving
HS-DSCH cell (target cell/Node B) and stops communication with the
old serving HS-DSCH cell (source cell/Node B). This procedure is
also called serving HS-DSCH cell change.
[0009] With the introduction of the enhanced DCH in the UL, the
WTRU must also maintain a connection with a serving E-DCH cell. The
serving HS-DSCH cell and serving E-DCH cell must be identical
throughout the WTRU connection. Therefore, when a serving HS-DSCH
cell change occurs, a serving E-DCH cell change also occurs. The
combined procedure is also referred to as the serving cell
change.
[0010] An important aspect in handover is the selection of a "best
cell". Accordingly, the WTRU continuously measures the signal
strength of the common pilot channel (CPI CH) of the neighboring
cells. If the measured signal of the neighboring cell exceeds that
of the serving cell, the WTRU reports to the radio network
controller (RNC) a change of best cell via a Radio Resource
Controller (RRC) measurement report event 1D. The measurement
report contains the measured value and cell identification (cell
ID). The RNC then makes the final determination as to whether a
serving cell change should occur.
[0011] A serving cell change can also occur via other RRC
measurement report events, such as event 1A or event 1C, or as part
of an active set update procedure.
[0012] Upon reception of these events, the RNC determines whether
to perform a handover to a new cell. The serving RNC (SRNC)
requests the controlling RNC (CRNC) to allocate high-speed downlink
shared channel (HS-DSCH) resources (e.g. as HS-DSCH radio network
transaction identifier (H-RNTI), high-speed shared control channel
(HS-SCCH) codes, hybrid automatic repeat-request (HARQ) resources,
etc.) and E-DCH resources (such as, E-RNTI, E-DCH Absolute Grant
Channel (E-AGCH) and serving E-DCH Relative Grant Channel (E-RGCH),
etc.) for the WTRU in the target cell via Radio Network Subsystem
Application Part (RNSAP) and/or Node-B Application Part (NEAP)
messages. Once the resources are reserved, the CRNC provides all
the information to the SRNC which in turn transmits an RRC handover
message to the WTRU. The RRC message, which can indicate a serving
HS-DSCH cell change includes, but is not limited, to: a physical
channel reconfiguration, transport channel reconfiguration, radio
bearer reconfiguration, and active set update.
[0013] The RRC handover message provides the WTRU with the radio
access parameters required for the WTRU to start monitoring the
target cell. In addition, the RRC message may provide an activation
time which notifies the WTRU at which time the handover should
occur.
[0014] Handovers can be synchronized or unsynchronized. In an
unsynchronized handover the network and the WTRU do not activate
the resources and switch at the same time. The activation time for
the WTRU is set to "now". This reduces the delays associated with
the handover procedure; however it increases the probability of
losing data.
[0015] In a synchronized handover, the network and the WTRU perform
the change of resources simultaneously. The network sets the
activation time to a conservative value to account for any kind of
delays such as scheduling delay, retransmissions, configuration
time etc. While the synchronized handovers minimize data losses, it
does result in higher delays.
[0016] The RRC handover message is transmitted to the WTRU via the
source Node-B. The delay associated with the serving HS-DSCH cell
change procedure may cause the handover message to fail, thus
resulting in an unacceptable rate of dropped cells. As a result, to
optimize the serving HS-DSCH cell procedure, a pre-loading
(pre-configuration) of the WTRU and the Node-B with HS-DSCH or
E-DCH related configuration has been proposed. When a cell is added
to the active set, the WTRU and the Node-B are pre-configured with
the radio link (RL) reconfiguration prepare/ready phase. When a
change in the best cell occurs (i.e. an event 1D), the
configuration of the target Node-B, which is already
pre-configured, can be activated by the RNC.
[0017] Parallel monitoring of the source Node-B HS-SCCH and the
target Node-B HS-SCCH has also been proposed. Upon a change of the
best cell, the WTRU transmits an event 1D measurement report. After
waiting for a configurable amount of time, the WTRU starts
monitoring the pre-loaded target Node-B's HS-SCCH in addition to
the HS-SC CH of the source Node-B. In performing these steps the
service discontinuity is reduced.
[0018] Another alternative to optimize the serving HS-DSCH cell
procedure is for the WTRU only to monitor one cell at a time. Once
an event 1D is triggered, the WTRU provides the network with the
time at which the handover will occur, i.e. the connection frame
number (CFN), in the measurement report message. At the given CFN,
the WTRU will then stop monitoring the source cell and move to the
target cell.
[0019] Implicit re-pointing to the target Node-B at a first
scheduling occurrence may also be used. When the RNC authorizes the
handover and the target Node-B is configured and ready, the RNC can
schedule the WTRU on one of the HS-SCCHs that is monitored by the
WTRU. The first scheduling occurrence from the target Node-B
implicitly confirms a successful handover, thus a handover complete
message is transmitted to the RNC. To avoid packet loss, the source
Node-B can provide the RNC a status message indicating the amount
of data that still needs to be transmitted.
[0020] The handover (or re-pointing) indication can also be
transmitted over the target Node-B, via an HS-SCCH order, or a
serving cell change channel (SCCCH), which uses the same
channelization code as the E-RGCH and E-DCH HARQ Acknowledgement
Indicator Channel (E-HICH) but with a different signature
sequence.
[0021] The WTRU acknowledges the handover indication by changing
the UL scrambling code, or by using a special value of the channel
quality indicator (CQI) (i.e. 31) or the Scheduling Information
(SI).
[0022] The introduction of a second carrier in the downlink impacts
existing mobility procedures. The enhancements to the serving cell
change procedure have been optimized in the context of single
carrier operation. When a second carrier is introduced the enhanced
serving cell change procedure does not take into account both
carriers. Therefore, there exists a need for an improved method and
apparatus for dual serving cell change.
SUMMARY
[0023] A method and apparatus for implementing serving cell change
in a multi-cell wireless transmit receive unit (WTRU) are
disclosed. Serving cell information is received and stored by the
WTRU to preconfigure a primary and secondary serving cell of an
added cell to an active set. At least one of the preconfigured
primary and secondary serving cells are monitored for a handover
indication. Serving cell change is to the primary and secondary
serving cells is performed using the preconfigured serving cell
information upon receipt of a handover indication.
BRIEF DESCRIPTION OF THE DRAWINGS
[0024] A more detailed understanding may be had from the following
description, given by way of example in conjunction with the
accompanying drawings wherein:
[0025] FIG. 1 is a diagram of an example wireless communication
system;
[0026] FIG. 2 is a diagram of a dual-cell operable Wireless
Transmit Receive Unit (WTRU);
[0027] FIG. 3 is an example flow diagram of a method for
restricting access to a cell using carrier priority; and
[0028] FIG. 4 is an example deployment wherein Node Bs use multiple
frequencies to communicate with a WTRU configured with dual cell
HSDPA and HSUPA.
DETAILED DESCRIPTION
[0029] When referred to hereafter, the terminology "wireless
transmit/receive unit (WTRU)" includes but is not limited to a user
equipment (UE), a mobile station, a fixed or mobile subscriber
unit, a pager, a cellular telephone, a personal digital assistant
(PDA), a computer, or any other type of user device capable of
operating in a wireless environment. When referred to hereafter,
the terminology "base station" includes but is not limited to a
Node-B, a site controller, an access point (AP), or any other type
of interfacing device capable of operating in a wireless
environment.
[0030] When referred to hereafter, the terminology "sector"
includes but is not limited to one or more cells belonging to the
same base station and covering the same geographical area. The term
sector can also be referred to as a carrier set, which includes one
or more cells belonging to the same base station covering the same
geographical area. Even though the definition of a sector or
carrier set is described as carrier frequencies covering the same
geographical area, the same definition and concept applies to the
case where the cells within a carrier set have different coverage
areas (i.e. one covers only a subset of the geographical area).
This can depend on deployment or whether the different carriers
belong to the same band or not. The terminology "Anchor Carrier"
includes but is not limited to a downlink frequency carrier
associated with an uplink frequency carrier assigned to a WTRU.
More specifically, a WTRU's anchor cell operates with all the
physical channels, including Dedicated Physical Channel
(DPCH)/Fractional DPCH (F-DPCH), enhanced Dedicated Channel (E-DCH)
HARQ Acknowledgement Indicator Channel (E-HICH), E-DCH Absolute
Grant Channel (E-AGCH), and E-DCH Relative Grant Channel (E-RGCH).
Additionally, an anchor carrier can also be referred to as the
carrier which has an associated UL carrier, where the HS-DPCCH is
transmitted on. The terminology "Anchor carrier" and "primary
carrier" are used interchangeably.
[0031] The terminology "Supplementary Carrier" refers to a downlink
frequency carrier which is not the Anchor Carrier. The terminology
"dual cell" refers to two carriers over which HS-DSCH transmissions
is performed and received by the WTRU.
[0032] With multi-carrier operation, more than two (2) cells can be
configured for simultaneous HS-DSCH transmission, however the
concepts described herein are still applicable, where the
definition of the anchor carrier remains the same and the WTRU may
have more than one supplementary carrier. Even though the invention
is described in terms of dual carrier HSDPA operation, it is also
applicable to dual carrier uplink operation and multi carrier, UL
and DL operations.
[0033] When referred to hereafter, a serving sector or serving
carrier set includes the serving anchor and supplementary cells.
Source and target serving sector refers to the old serving sector
prior to the handover (i.e. the set of source anchor and
supplementary cells) and the new serving sector after the handover
has occurred (i.e. the set of target anchor and supplementary
cells) in which the WTRU is performing HS-DSCH reception,
respectively. Source anchor carrier refers to the carrier frequency
being used in the source anchor serving cell. Source supplementary
carrier refers to the carrier frequency being used in the source
supplementary serving cell. Target anchor carrier refers to the
carrier frequency expected to be used in the target anchor cell in
the target sector. The expected target anchor carrier may
correspond to the same anchor frequency as the source anchor cell.
Alternatively it may correspond to the carrier which has best CPICH
quality measurement in the target sector, which can be anticipated
to become the anchor carrier/cell. Target supplementary carrier
refers to the carrier frequency expected to be used in the target
supplementary cell in the target sector. Anchor frequency refers to
the frequency being used for the anchor carrier in the current
serving cell. Supplementary frequency refers to the frequency being
used for the supplementary carrier in the current serving cell.
[0034] FIG. 1 shows a wireless communication system 100 including a
plurality of WTRUs 110, a Node-B 120, a controlling radio network
controller (CRNC) 130, a serving radio network controller (SRNC)
140, and a core network 150. Node-B 120, CRNC 130 and SRNC 140 are
collectively known as a Universal Terrestrial Radio Access Network
(UTRAN) in 3GPP terminology.
[0035] As shown in FIG. 1, WTRU s 110 are in communication with the
Node-B 120, which is in communication with CRNC 130 and SRNC 140.
Although three WTRUs 110, one Node-B 120, one CRNC 130, and one
SRNC 140 are shown in FIG. 1, any combination of wireless and wired
devices may be included in wireless communication system 100.
[0036] FIG. 2 is a functional block diagram 200 of a multi-cell
capable WTRU 110 of wireless communication system 100 of FIG. 1.
The WTRU 110 is configured to perform and enhance mobility
procedures in, for example, a CELL Dedicated Channel (DCH)
(CELL_DCH) state, or other states.
[0037] In addition to the components that may be found in a typical
WTRU, a multi-cell WTRU 110 includes an antenna 118, for
facilitating the transmission and reception of wireless data, a
receiver 116 configured to receive multi-cell wireless signals, a
processor 115 configured to implement mobility procedures for
multi-cell operation and a transmitter 117. The receiver 116 may be
a single receiver capable of receiving communications over two or
more carriers, or a collection of receivers, such as receivers that
are each capable of receiving communications over a single
carrier.
[0038] The antenna 118 may comprise a single antenna or multiple
antennas. One example configuration of a multiple receiver/multiple
antenna embodiment is where each antenna is connected to its own
receiver.
[0039] In the example configuration of FIG. 2, the receiver 116 and
the transmitter 117 are in communication with the processor 115.
The antenna 118 is in communication with both the receiver 116 and
the transmitter 117 to facilitate the transmission and reception of
wireless data. A handover indication includes but it is not limited
to a high speed shared control channel (HS-SCCH) order; a decoding
of the HS-SCCH with a preconfigured high speed downlink shared
channel (HS-DSCH) radio network transaction identifier (H-R);
H-RNTI; an RRC message indicating handover; and scheduling on the
E-AGCH with the WTRU's preconfigured E-RNTI.
[0040] In accordance with a disclosed method of performing a
dual-cell serving cell change, one or more of the cells in a target
sector are monitored to receive a handover indication. A handover
indication includes, but it not limited to, a high speed shared
control channel (HS-SCCH) order; a decoding of the HS-SCCH with a
preconfigured high speed downlink shared channel (HS-DSCH) radio
network transaction identifier (H-R); H-RNTI; an RRC message
indicating handover; and scheduling on the E-AGCH with the WTRU's
preconfigured E-RNTI.
[0041] In order to perform the handover, WTRU 110 monitors the
cells in the target sector, which requires a set of
pre-configurations and a set of rules of when and how the
monitoring should be performed.
[0042] Accordingly, the high speed packet access (HSPA) resources
for both carriers (anchor and supplementary cells) in all sectors
in the active set are preconfigured by the network. As such, in
addition to the anchor cell configuration parameters, the network
also pre-configures WTRU 110 with the set of parameters for the
secondary cell as part of the active set update procedure.
Alternatively, all of the sectors in the E-DCH active set are
pre-configured. Sectors in the active set correspond to the sectors
in which the cells of the active set belong (i.e., the cells in
which WTRU 110 is in soft handover). The pre-configuration of both
cells belonging to a sector in the active set is a network
decision. If no pre-configuration information is available for the
supplementary carrier, WTRU 110 uses a single serving cell change
procedure.
[0043] WTRU 110 is preloaded with the pre-configuration information
(e.g., configuration parameters) required for the anchor cell, as
well as, the information required to perform reception, and
optionally transmission, in the supplementary frequency. Such
configuration parameters may include, but are not limited to, the
Secondary HS-DSCH serving cell information, such as HS-SCCH codes
and a WTRU H-RNTI. Alternatively, for the supplementary cell, the
network may pre-configure both carriers of the sector in the active
set with the full set of resources that a cell would require if it
were to become an anchor cell or a full set of parameters required
by WTRU 110 to configure and operate with dual carriers in the
uplink, such as the Secondary E-DCH serving cell information. For
example, such parameters may include, the E-AGCH, E-HICH, E-RGCH,
F-DPCH, E-RNTI(s) etc.
[0044] The pre-configuration of resources may be performed as part
of an Active Set Update procedure when a cell is added to the
active set. For dual carrier HSDPA, the secondary pre-configuration
for HS-DSCH is provided as part of the active set update message
when a new cell (as measured on the anchor frequency) is added to
the active set. In the case of dual carrier uplink, the
pre-configuration of the secondary uplink carrier may be provided
when the cell is being added to the secondary active set of the UE.
Alternatively, both UL and DL secondary pre-configuration are
provided when a cell in the anchor frequency is added to the active
set. Optionally, if a cell in the secondary frequency is added to
the secondary active set of WTRU 110 and the anchor carrier
associated with the secondary cell is not part of the primary
active set, no UL pre-configuration is provided to WTRU 110.
Alternatively, if the active set update is adding a cell in the
anchor frequency to the active set, WTRU 110 may be preconfigured
with HS-DSCH parameters and, if the secondary cell has already been
added to the secondary active set, the E-DCH parameters for
secondary uplink operation are pre-configured. In another
alternative, WTRU 110 may be preconfigured with resources only for
the anchor cell, and the resources for the target supplementary
cell are received via an RRC handover message received over the
target anchor cell.
[0045] When a measurement event resulting in a change of the best
cell between two sectors occurs, WTRU 110 transmits a measurement
report and awaits a network confirmation or message to perform the
handover. For an enhanced dual-cell serving cell change procedure,
WTRU 110 may wait for this indication or message on one or more of
the cells in the target sector, which have been pre-configured.
[0046] Because WTRU 110 may be receiving data over both carriers in
the source sector, a method to allow WTRU 110 to perform reception
on the target cells includes WTRU 110 monitoring three cells, the
supplementary cell and anchor cell, from the source sector, and
only one of the cells in the target sector.
[0047] The carrier frequency with the best CPICH quality
measurement, which is anticipated to become the anchor carrier, may
be monitored for a handover indication. For dual carrier HSDPA, the
target carrier frequency that WTRU 110 monitors for the handover
indication corresponds to the frequency used in the source anchor
cell. This may also be used for dual carrier HSUPA.
[0048] When dual carrier HSUPA is implemented in the WTRU, since
the CPICH quality is measured on both frequency, this carrier
frequency may correspond to the source anchor frequency, the source
supplementary frequency, or in the alternative, a frequency not
currently being used by the source cell. For dual carrier HSUPA,
since the WTRU measures both cells, the WTRU can monitor the target
HS-SCCH secondary cell for the handover indication if the CPICH
measurement is better than the anchor, or if the best cell
corresponds to the secondary target cell.
[0049] Since only one of the target carriers of the target sector
is monitored, WTRU 110 waits until a handover indication is
received on the monitored target carrier, or until a RRC handover
message is received over the source carriers. Upon reception of the
handover indication, WTRU 110 may then stop receiving the HS-DSCH
in the source cells (i.e. anchor and supplementary), and configure
WTRU 110 to start monitoring and receiving the HS-DSCH in both the
supplementary and anchor carrier of the target cells, if the
resources are pre-configured. If the resources are not
preconfigured for the secondary carrier, WTRU 110 may stop
receiving on the source sector and start receiving only from the
pre-configured carrier, and wait to receive the secondary carrier
configuration from an RRC message.
[0050] If DC-HSUPA is configured, and the secondary information are
preconfigured, WTRU 110 may also start DC-HSUPA transmission in the
secondary carrier within the required time. WTRU 110 may start
secondary E-DCH transmission as soon as the serving cell change is
completed, or alternatively, wait for a HS-SCCH order to activate
dual carrier transmission. When the status of secondary E-DCH
transmission in the secondary source cell is active, WTRU 110 may
immediately reconfigure to the target cell and start E-DCH
transmission.
[0051] As an option, if the status of the secondary E-DCH
transmission in the source secondary cell was inactive, WTRU 110
may not start E-DCH transmission right away. The RRC configures the
physical layer and WTRU 110 with the preconfigured information, but
WTRU 110 has to receive an HS-SCCH order activating DC-HSUPA
operation. A similar concept to the initiation of E-DCH
transmission on the secondary target cell may also apply if WTRU
110 received a RRC handover message instead of a HS-SCCH order.
[0052] If a special value of the CQI is used for a handover
acknowledgment WTRU 110 may then transmit the CQI over the anchor
HS-DPCCH, or alternatively on both HS-DPCCHs to increase the
reliability of the acknowledgment message.
[0053] A flow diagram of this disclosed method is shown in FIG. 3.
A WTRU is preloaded with the configuration parameters for the cells
target sector (step 300). The WTRU then monitors the cells in the
target sector using the preloaded information (step 301). When a
measurement event results in a change of the best cell between two
sectors, the WTRU transmits a measurement and waits to receive a
message from the RNC to perform handover (step 302). The WTRU
monitors the target carrier (i.e., anchor or supplementary carrier)
for this message (i.e., handover indication) (step 303). Upon
receipt of the handover indication, the WTRU ceases receiving the
HS-DSCH in the source cells, and starts monitoring and receiving
the HS-DSCH in the target cells (step 304).
[0054] In an alternative method, WTRU 110 simultaneously monitors
both the supplementary carrier and the anchor carrier on both
sectors. This requires WTRU 110 to monitor four cells, i.e. the
HS-SCCH of two anchor carriers and two supplementary carriers. WTRU
110 may be configured to only monitor the full HS-SCCH set of the
target carriers, or alternatively, just a subset of the HS-SC CH of
the target carriers. Once a handover indication is received, WTRU
110 starts monitoring the full set in the target cell.
[0055] In accordance with this method, the handover indication may
be scheduled on both carriers to increase the reliability of the
message and probability of fast detection by WTRU 110. The carrier
over which the handover indication was sent and received on, may
also indicate the carrier that should become the primary carrier
once the serving cell(s) change is performed. Therefore, if the
HS-SCCH indication was received over the secondary carrier, the
target secondary carrier would become the new primary serving cell
(i.e. the primary carrier). Upon reception of the handover
indication, WTRU 110 may acknowledge the handover indication using
an L1, L2, or L3 message. If an L1 message is used, for example,
WTRU 110 may transmit a special value of the CQI.
[0056] The CQI may be transmitted over the HS-DPCCH of the
corresponding carrier in which the indication was received, both
HS-DPCCH used for the two carriers regardless of the carrier in
which it was received, and/or on the anchor HS-DPCCH (or
alternatively only on the supplementary) regardless of the carrier
in which it was received. In the latter, the other carrier may be
used to report the real CQI value to be used for faster scheduling
and AMC from the network.
[0057] In another alternative, WTRU 110 only monitors the HS-SCCH
of one carrier from each source and target sector (i.e. two
carriers). More specifically, WTRU 110 may stop monitoring the
supplementary cell in the source sector and monitor only one of the
carriers of the target sector. This allows WTRU 110 to reduce the
complexity of monitoring more than two HS-SCCH sources, while still
monitoring the source cell and not interrupting voice call
continuity.
[0058] For monitoring the target sector, WTRU 110 may monitor the
carrier frequency corresponding to the same carrier as the anchor
cell in the source sector or the carrier frequency corresponding to
the same carrier frequency as the supplementary cell in the source
sector, WTRU 110 alternatively may then be configured to determine
which carrier frequency to monitor based on the CPICH quality
measurement in the target sector. The carrier frequency with the
best CPICH quality measurement, which is anticipated to become the
anchor carrier, may be monitored for a handover indication. This
carrier frequency may correspond to the source anchor frequency, to
the source supplementary frequency, or alternatively to a frequency
not currently being used by the source cell.
[0059] WTRU 110 in an alternative, may stop monitoring the
supplementary carrier of the source cell and start monitoring the
supplementary carrier of the target cell. The WTRU continues to
monitoring the anchor carrier of the source cell.
[0060] WTRU 110 may also stop monitoring the anchor carrier HS-SCCH
in the source sector while continuing to monitor the supplementary
cell in the source sector. WTRU 110 can select which carrier to
monitor in the target sector based on similar criteria to the ones
described above.
[0061] If WTRU 110 stops monitoring one of the carriers of the
source sector after transmitting the measurement report, WTRU 110
transmit an indication to the corresponding source cell that it has
interrupted reception to that cell. This notification may be made
by using one or a combination L1, L2 or L3 signaling.
[0062] L1 signaling is used, a special value of the CQI may be
reported on the corresponding HS-DPCCH. Upon reception of this CQI
value, the source Node-B stops scheduling data over the
corresponding carrier. Alternatively, WTRU 110 may report a
fictitious low CQI value, for example 0, which implicitly forces
the Node-B to stop scheduling WTRU 110 on the corresponding
carrier.
[0063] Using L2 signaling for this notification includes
transmitting a special reserved value of the SI to the source
Node-B, or the message is appended to a MAC-ids payload, using a
special value of the logical channel identifier (LCH-ID) to
indicate the presence of this message.
[0064] For L3 signaling, the measurement report may include the
time at which WTRU 110 will stop monitoring the corresponding
source carrier, the time at which it will stop monitoring the
source anchor carrier as well. The RNC signals to the source Node-B
to stop scheduling WTRU 110 in the source carrier. Alternatively,
WTRU 110 may report the CFN at which the measurement report was
transmitted and both the RNC and WTRU 110 are pre-configured with a
time at which WTRU 110 should stop monitoring one carrier. A time
in which the handover should be performed after the CFN at which
the message was transmitted may also be included in the
pre-configuration.
[0065] Once the handover indication is received by WTRU 110, WTRU
110 may then configure the supplementary carrier, or the anchor
carrier in the target cell if pre-configured) and stop monitoring
the source cell.
[0066] In another alternative method for allowing WTRU 110 to
perform reception on the target cells includes WTRU 110 ceasing
monitoring the HS-SCCH on both cells in the source sector, and
starting monitoring both carriers on the target sector.
Alternatively, only the anchor carrier in the target cell is
monitored until a handover indication is received.
[0067] The time at which WTRU 110 stops monitoring the source cells
and starts monitoring the target cells may be signaled by WTRU 110
to the network (via the CFN). Alternatively, WTRU 110 may be
configured to start monitoring the target cells at a predefined, or
a configured amount of time after the measurement report is
transmitted. In this case, WTRU 110 may then transmit the CFN at
which the measurement report was prepared to the network to help
synchronize the handover procedure.
[0068] An enhanced inter-frequency change method is disclosed
wherein WTRU 110 may change its anchor frequency and supplementary
frequency, or swap the anchor frequency and supplementary frequency
within the same sector using an enhanced carrier change or swap
procedure. WTRU 110 may also perform a serving dual cell change
with a simultaneous anchor frequency change.
[0069] The method includes pre-configuring the current
supplementary cell of the serving sector with DL/UL information
required by WTRU 110 for potential use as an anchor cell. For
example, WTRU 110 is pre-configured with the F-DPCH, E-AGCH,
serving R-GCH, C-RNTI, E-RNTI(s), and other configurations required
for WTRU 110 to configure another (or a supplementary) carrier as
an anchor carrier. The network may also pre-configure the
supplementary cells of all sectors in the active set with
information required by WTRU 110 to use this frequency as an anchor
cell, or to use this frequency for dual carrier uplink operation,
such as secondary E-DCH serving cell information (i.e. E-AGCH,
E-RGCH, E-HICH, F-DPCH, etc). The information is stored in WTRU 110
and deleted when the serving cell is removed from the active set.
Alternatively, only a sub-set of the above mentioned parameters are
pre-configured. WTRU 110 may use the same channelization codes and
information which were configured in the anchor cell and apply the
same configuration to the second frequency. Other parameters, for
example, C-RNTI and E-RNTI(s) may also need to be pre-loaded.
[0070] Alternatively, the supplementary carrier is pre-configured
as an anchor carrier for all cells of the active set.
[0071] In accordance with this method, a measurement report may
trigger a swap of the anchor frequency and supplementary frequency
if a trigger occurs. This trigger may occur when the cell of the
supplementary frequency is the best cell for a measurement report
triggered by event 1D message (i.e., a new cell in the
supplementary frequency has become better than the current cell in
the source supplementary, and optionally source anchor frequency),
or another similar event, such as, an inter-frequency event,
wherein the quality of the secondary cell has become better than
the quality of the anchor cell by a configured threshold and for a
configured amount of time.
[0072] The quality (e.g. CPICH Ee/No) of the anchor carrier is
lower than a threshold or has been lower than a threshold for a
pre-determined period of time may also be a trigger. Stated another
way, the quality of the supplementary carrier is higher than a
threshold for a predetermined period of time. The threshold may be
a function of the CPICH Ee/No of the supplementary carrier.
[0073] Another trigger may occur when the quality of the anchor
carrier is lower than a first threshold and the quality of the
supplementary carrier is higher than a second threshold. A
combination of these in the measurement report may also trigger a
frequency swap (i.e. an inter-frequency handover) or a serving cell
change with a simultaneous change of anchor frequency.
[0074] When a measurement report is triggered according to one of
the criteria mentioned above, this would result in WTRU 110
changing the anchor carrier frequency within the serving sector, if
the anchor carrier and the supplementary carrier are swapped within
the serving sector, or changing the anchor carrier frequency while
changing the serving cell or sector at the same time. Once the
measurement report has been triggered, WTRU 110 may continue to
listen to both the anchor cell and the supplementary cell and wait
for an HS-SCCH order, or handover indication, to indicate that the
handover should be performed. The monitoring of the HS-SCCH should
be performed according to one of the methods disclosed above.
[0075] Where WTRU 110 will not have a secondary UL configured at
the end of the handover, at the time of handover message reception,
WTRU 110 may stop listening to, or receiving, the DL control
channels (i.e. F-DPCH, E-AGCH, E-HICH and E-RGCH) in the anchor
frequency, continue the HS-SCCH and HS-DPSCH monitoring in the
anchor carrier, and consider this carrier as the supplementary
carrier. WTRU 110 may also reconfigure the supplementary carrier to
start acting as an anchor carrier (e.g., WTRU 110 starts monitoring
the F-DPCH, E-AGCH, E-RGCH, etc. in the new anchor carrier), and
start transmission of the DPCCH and HS-DPCCH in the new
frequency.
[0076] WTRU 110 may also perform the synchronization procedure with
the new frequency (i.e., synchronization A). If the handover
results in a change of an UL carrier frequency, WTRU 110 starts the
power control loop with the new UL frequency as soon as the
handover is complete and the new physical channels (i.e. F-DPCH or
DPCCH) are established. For the initial DPCCH power value, WTRU 110
may use the last DPCCH power used in the old anchor carrier with a
possible addition of a network configurable DPCCH power offset.
[0077] If WTRU 110 does not support soft handover with radio links
in different frequencies, then all configured DL radio links in the
active set for the other cells in the previous frequency, other
than the serving cell are autonomously released by WTRU 110.
[0078] The UL radio link may also be maintained if WTRU 110
maintains the same UL frequency.
[0079] The WTRU may wait for an RRC handover message to be
configured with the new parameters for the new active set in the
new carrier.
[0080] In the case where UL dual carrier is configured, the
changing of the used anchor frequency requires WTRU 110 to stop
DPCCH and HS-DPCCH transmission in the old anchor carrier frequency
and start transmission in the new anchor carrier frequency (i.e.,
the old supplementary frequency). The change when DC-HSUPA is
configured or when the information if pre-configured in the target
sector, requires less changes and thus it is much faster to
perform. WTRU 110 continues to use the same configured physical
channels and continues with the same active set, but changes the
logical association from anchor to supplementary, and vice
versa.
[0081] In another alternative, WTRU 110 may switch the anchor
frequency with the supplementary frequency (i.e., the old anchor
carrier is no longer being used). When the anchor frequency is
switched, WTRU 110 may monitor only the supplementary carrier for a
handover indication while continuing reception in the anchor
carrier. Once a handover indication is received, WTRU 110 may stop
listen to the old anchor frequency, and/or reconfigure the
supplementary carrier to perform as an anchor carrier. For example,
WTRU 110 starts monitoring the F-DPCH, E-AGCH, E-RGCH, etc. in the
new anchor carrier.
[0082] WTRU 110 may also initiate the synchronization procedure
with the new frequency. If the handover results in a change of the
UL carrier frequency, WTRU 110 may start the power control loop
with the new UL frequency as soon as the handover is complete. For
the initial DPCCH power value, WTRU 110 may use the last DPCCH
power used in the old anchor carrier with a possible addition of a
network configurable DPCCH power offset.
[0083] If WTRU 110 does not support soft handover with radio links
in different frequencies, all of the configured DL radio links in
the active set for the other cells, other than the serving cell,
are autonomously released by WTRU 110. It is an option to have the
UL radio link be maintained if WTRU 110 maintains the same UL
frequency.
[0084] WTRU 110 may also wait for an RRC handover message to be
configured with the new parameters for the new active set in the
new carrier and the new supplementary carrier.
[0085] As indicated above, WTRU 110 may be configured with dual
cell HSDPA and HSUPA. FIG. 4 illustrated three scenarios in which
the Node Buses one or more of available frequencies to communicate
with WTRU 110. Referring to FIG. 4, in a first scenario, WTRU 110
is operating in single carrier operation and performing HS-DSCH and
E-DCH reception, and in soft handover with NB 2 and 3. In an
alternative, when NB (or cell) 2 and 3 are added to the active set,
since they have dual carrier capabilities, WTRU 110 is
preconfigured with primary serving cell information. WTRU 110 may
also be preconfigured with secondary HS-DSCH and E-DCH serving cell
information. This preconfigured information may include, but is not
limited to, E-AGCH, E-RGCH, HS-SCCH, H-RNTI, E-RNTI, F-DPCH, etc.
Alternatively, only the secondary HS-DSCH serving cell
pre-configuration is provided.
[0086] As WTRU 110 moves from scenario 1 to scenario 2 in FIG. 4, a
change of best cell occurs (i.e., event 1D is triggered). When only
the secondary HS-DSCH serving cell information is provided, WTRU
110 monitors the anchor HS-DSCH serving cell for a handover
indication. If a handover indication is received, WTRU 110 performs
a fast serving cell change to both the primary and secondary
HS-DSCH serving cell. In the case where both secondary HS-DSCH and
E-DCH serving cell information are preconfigured, WTRU 110, after
receiving the HS-SCCH order over the anchor frequency, configures
primary and secondary HS-DSCH reception and starts both primary and
secondary E-DCH transmission. WTRU 110 may perform a
synchronization procedure on the secondary carrier when the serving
cell(s) change is performed. This is due to the fact that no
ongoing secondary E-DCH transmission was available in the source
cells.
[0087] In an alternative, the RRC configures the secondary E-DCH
transmission parameters, but transmission over the secondary E-DCH
does not start until an HS-SCCH order activating the secondary
carrier is received by WTRU 110. The secondary active set is
updated by the network according to the measurements sent by WTRU
110. In the case where, one of the cells in the secondary active
set is not present in the anchor active set (like NB 4 in FIG. 4
above), the network may provide WTRU 110 with a set of
pre-configured secondary E-DCH serving cell parameters and a set of
HS-DSCH parameters for cell 4. Alternatively, the network may
pre-configure WTRU 110 with all parameters for this carrier to
become an anchor carrier if necessary.
[0088] As WTRU 110 moves from scenario 2 to scenario 3, where an
event 1D is triggered and the best cell is a cell that only belongs
to the secondary frequency and no primary cell is present, a fast
frequency change may occur. Once WTRU 110 triggers a measurement
report with event 1D, indicating the cell 4 as the best cell, WTRU
110 continues monitoring the source HS-DSCH and the source E-DCH
cell and simultaneously the first HS-SCCH set provided in the
preconfigured secondary carrier information. Upon reception of an
order over the HS-SCCH in the secondary frequency, WTRU 110 may
perform a serving cell change to cell 4 and at the same time a fast
primary frequency change. Since WTRU 110 is already synchronized on
the secondary carrier and already has an active set, WTRU 110 may
continue transmission over the new primary serving cells without
the need to perform a synchronization procedure. The radio links
previously established in fl are released, and WTRU 110 performs
only single carrier operation. The preconfigured information for
the cells in the active set of the fl carrier may be maintained and
stored in WTRU 110 and treated as secondary pre-configured HS-DSCH
and E-DCH serving cell information.
[0089] If WTRU 110 is in scenario 2 (i.e., in cell 2) and a change
of serving cell is detected (i.e. event 1D) and the new best cell
could be in the secondary frequency (i.e. f2), WTRU 110 may receive
a serving change command that performs a serving cell change and
also a change of anchor and secondary carrier. In this case, WTRU
110 may monitor the target anchor HS-DSCH cell for a handover
indication and perform the handover to the secondary carrier.
Alternatively, WTRU 110 may monitor both target anchor and
secondary HS-DSCH, and if the order is received over the anchor
HS-DSCH cell WTRU 110 performs a serving cell change, while keeping
the same anchor carrier. In another alternative, if the order is
received over the secondary HS-DSCH cell, WTRU 110 performs a
serving cell change and configures the secondary frequency (f2) as
the anchor carrier of WTRU 110 and starts all anchor carrier
operations, such as transmission of DPCCH and HS-DPCCH over this
new frequency. The active sets of f1 and f2 are maintained and no
synchronization procedures need to be initiated.
[0090] Although the disclosure is described within the context of
3GPP WCDMA systems, it should be understood that it is applicable
to any wireless communications system that can support dual (or
multi) cell (or carrier) operations.
[0091] Although features and elements are described above in
particular combinations, each feature or element can be used alone
without the other features and elements or in various combinations
with or without other features and elements. The methods or flow
charts provided herein may be implemented in a computer program,
software, or firmware incorporated in a computer-readable storage
medium for execution by a general purpose computer or a processor.
Examples of computer readable storage mediums include a read only
memory (ROM), a random access memory (RAM), a register, cache
memory, semiconductor memory devices, magnetic media such as
internal hard disks and removable disks, magneto-optical media, and
optical media such as CD-ROM disks, and digital versatile disks
(DVDs).
[0092] Suitable processors include, by way of example, a general
purpose processor, a special purpose processor, a conventional
processor, a digital signal processor (DSP), a plurality of
microprocessors, one or more microprocessors in association with a
DSP core, a controller, a microcontroller, Application Specific
Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs)
circuits, any other type of integrated circuit (IC), and/or a state
machine.
[0093] A processor in association with software may be used to
implement a radio frequency transceiver for use in a wireless
transmit receive unit (WTRU), user equipment (UE), terminal, base
station, radio network controller (RNC), or any host computer. The
WTRU may be used in conjunction with modules, implemented in
hardware and/or software, such as a camera, a video camera module,
a videophone, a speakerphone, a vibration device, a speaker, a
microphone, a television transceiver, a hands free headset, a
keyboard, a Bluetooth.RTM. module, a frequency modulated (FM) radio
unit, a liquid crystal display (LCD) display unit, an organic
light-emitting diode (OLED) display unit, a digital music player, a
media player, a video game player module, an Internet browser,
and/or any wireless local area network (WLAN) or Ultra Wide Band
(UWB) module.
* * * * *