Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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[0001] WIRELESS COMMUNICATION METHOD AND SYSTEM
FOR ACTIVATING MULTIPLE SERVICE BEARERS
VIA EFFICIENT PACKET DATA PROTOCOL
CONTEXT ACTIVATION PROCEDURES
[0002] FIELD OF INVENTION
[0003] The present invention generally relates to wireless communication
systems. More particularly, the present invention is related to methods and
apparatus for activating multiple service bearers using a single secondary
packet
data, protocol (PDP) context activation procedure in a Third Generation
Partnership Project (3GPP) system, (i.e., General Packet Radio Service (GPRS)
and Universal Mobile Telecommunications System), and Long Term Evolution
(LTE) systems. The procedures can be implemented in a GPRS dual tunnel
approach and in a direct tunnel approach in GPRS and LTE systems.
[0004] BACKGROUND
[0005] Traditionally, cellular networks were designed for voice services
only. GPRS supports some types of data services, such as text messaging and
emails. However, more data services and multimedia services are being
introduced as applications running on cellular networks, such as Voice over
Internet Protocol (VoIP), Internet Protocol (IP) television (IPTV), or the
like. Cell
phones are changing from a voice service phone to a converged data centric
device, and the cellular network is evolving towards the next generation of
all IP
networks and packet services with IP multimedia subsystem (IMS)
infrastructure. Besides the need for a higher data rate, the cellular network
also
needs the architecture changes required to support IP applications and packet-
switched (PS) services more efficiently, (i.e., reducing delays due to
multiple
setup procedures and delay time for services data traffic due to excessive
processing at the various nodes of the network).
[0006] Figures 1-3 show signaling in a conventional wireless
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communication system 100 including a wireless transmit/receive unit (WTRU)
105, a radio access network (RAN) 110, a serving general packet radio service
(GPRS) support node (SGSN) 115 and a gateway GPRS support node (GGSN)
120. One packet data protocol (PDP) context is associated with one radio
access
bearer (RAB) for a 3GPP PS service. Thus, to support multiple services, one
primary PDP context activation and multiple secondary PDP context activation
procedures are needed to enable these services, as illustrated by Figures 1-3,
which are described by 3GPP technical specification (TS) 23.060. For example,
the data subscriber who wishes to connect to IMS-based services, (i.e., VoIP,
multimedia, and the like), and at the same time activates Web browsing, e-mail
service, fax service, and the like, has to perform a separate PDP context
activation for each service. By the time all of the services are running, the
subscriber may have waited for a considerable amount of time, similar to
waiting for a computer to boot up.
[0007] Currently for the 3GPP PS service, one PDP context is associated
with one RAB. Thus to support multiple services, one primary context and
multiple secondary PDP contexts need to be activated, as shown in Figures 1
and
2. Furthermore, to support IMS services, a primary PDP context for session
initiated protocol (SIP) signaling and secondary PDP context for each data
service, (to be activated), is always needed.
[0008] SUMMARY
[0009] The present invention provides a method and apparatus for 3GPP
systems, (i.e., GPRS, UMTS), and LTE systems, to reduce service setup delays
due to the multiple serial setup procedures and processing delay time for data
traffic services due to excessive processing at the various nodes of the
network.
The present invention proposes a simplified secondary PDP context activation
procedure that activates several services in a single step. The present
invention
re-uses the current 3GPP PDP context activation procedures for the allocation
of
an IP address, initiating service, and the establishment of tunneling between
the
different elements within the network, (i.e., RAN, SGSN, GGSN, IMS, and the
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like). The present invention allows for the activation of multiple PDP
contexts
using a single step secondaxy 'PDP context activation, where each service is
associated with certain service bearers in the Core Network (CN) and a
specific
RAB in the RAN. The present invention also allows for the establishment of
multiple RABs which are mapped to one PDP context for different QoS
requirements. These multiple PDP contexts can be established for special
requirements, (e.g., bundled services), or when the WTRU connects to multiple
PDNs.
[0010] The present invention reduces the delay for the secondary PDP
context activation and any modifications thereof when more services are
required. For example, a user configures a personal data assistant (PDA)
terminal to activate VoIP services, Video conferencing, an E-mail account, and
the like, when the PDA terminal powers up. According to the current procedures
in TS 23.060, the WTRU performs each procedure individually and sequentially.
The present invention reduces unnecessary steps that are used in activate
secondary PDP context procedures. The WTRU requests additional bearers by
sending a request to the RAN, (e.g., an eNodeB), which examines the request to
see if the additional bearer can fit within the allocated resources of the
current
PDP context, (i.e., a bearer). When an additional bearer can be added, the
eNodeB forwards the request to a mobility management entity (MME) for further
examination.
[0011] The service type of the request determines whether a secondary
PDP context is needed. A secondary PDP context is required if the service
requested is provided by a different PDN at a different anchor node. If the
same
PDN and anchor node provide the requested service, the MME forwards the
service request to the anchor node to allocate the necessary resources and
mapping of the network layer service access point identifier (NSAPI) requested
by the WTRU to the new service bearer. The anchor node is informed by the
tunnel endpoint identifier (TEID) of the supporting eNodeB in this process.
After
receiving an acknowledgment, the MME establishes the other end of the tunnel
by sending an RAB establishment request to an eNodeB, which is updated with
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the anchor node TEID. The MME then requests that the WTRU update its RAB
resources. The WTRU then responds with a completion notice to the eNodeB,
which in turn informs the MME that the process has been successfully
completed.
If an error or counter timeout occurs at the MME, the MME proceeds to release
the tunnel and the resources allocated previously.
[0012] The present invention is advantageous for the following reasons
over the prior art: 1) several bearers are allocated within the primary PDP
context; 2) single tunnel establishment vs. *3GPP (GPRS) two tunnels (new
architecture); and 3) reduced number of steps, (combining the secondary PDP
activation with an RAB establishment request).
[00131 BRIEF DESCRIPTION OF THE DRAWINGS
[00141 A more detailed understanding of the invention may be illustrated
from the following description of a preferred embodiment, given by way of
example and to be understood in conjunction with the accompanying drawing
wherein:
[00151 Figure 1 shows a conventional primary PDP context activation
procedure for lu mode in a conventional wireless coxnmunication system;
[0016] Figure 2 shows a conventional secondary PDP context activation
Procedure for lu mode in a conventional wireless communication system;
[00171 Figure 3 is a flow diagram of conventional PDP context activation
procedures in a conventional wireless communication system;
[00181 Figure 4 is a signal flow diagram of PDP context activation
procedures in an LTE system in accordance with one embodiment of the present
invention;
[00191 Figure 5 is a signal flow diagram of PDP context activation
procedures in an LTE system in accordance with another embodiment of the
present invention; and
[00201 Figure 6 shows the establishment of multiple PDP contexts for
multiple PDNs.
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[0021] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0022] 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.
[0023] In accordance with one embodiment of the present invention, Figure
4 shows the procedures for PDP context activation and RAB assignment in an
LTE system 400 including a WTRU 405, an eNodeB 410, an MME 415 and an
anchor node 420. No additional secondary PDP context activations are needed
for multiple sets of services. Dynamic requests of new services are
accommodated by RB establishments and releases between the WTRU 405 and
the eNodeB 410. -
[0024] Referring to Figure 4, in step 422, the WTRU 405 sends an activate
PDP context request message to the MME 415. The contents of the message
include, for example, NSAPI, transaction identifier (TI), PDP type, PDP
address,
(if the static PDP address is requested), access point name (APN), QoS,
service
list, and the like.
[0025] Note that the meaning of QoS request is different from the current
PDP context activation procedure. Currently, the QoS applies only for this PDP
context. The primary and secondary PDP context and the RABs mapped to them
respectively can have a different QoS. In accordance with the present
invention,
the QoS is a range that applies to all of the RABs belonging to this PDP
context,
and it is likely that the WTRU 405 has only one PDP context for one IP
address.
The service list is a new parameter that provides the range of IP services
that the
WTRU 405 desires to establish with a core network (CN) under this PDP context.
[0026] In step 424, the MME 415 validates the activate PDP context
request using a PDP type, PDP address, and APN provided by the WTRU 405.
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The MME 415 may restrict the requested QoS attributes, given its capabilities
and the current load. The MME 415 sends a create PDP context request
message, (PDP type, PDP address, APN, QoS negotiated, TEID, NSAPI, mobile
station international integrated services digital network (ISDN) number
(MSISDN), and the like), to the affected anchor node 420 (step 426). In step
428,
for a valid PDP context request, the anchor node 420 will create a PDP entry.
A
different PDP is associated with each service requested. In this case, if all
the
services are provided via/by the same gateway, (i.e., anchor node 420), then
there
is one IP address and multiple port numbers. Each port number is associated
with the service being activated. Additionally, in step 428, the anchor node
420
creates charging information for a valid PDP context request. Each service
will
be charged separately and according to different criterion. For example, video
calls may be charged differently than text messages. Therefore, each service
will
be have a different charge ID. The anchor node 420 then sends a create PDP
context response message to the MME 415 (step 430).
[0027] In steps 432, 434, 436 and 438, RAB setup is performed by the RAB
Assignment /RB Setup procedures as it is done currently. The QoS exchanged
between the RAN, (e.g., the eNodeB 510), and the CN, is for the specific RAB,
and it should be within the negotiated QoS of the PDP context. The identity of
the PDP context associated with this RAB is passed to the WTRU 405. In case
that the QoS of the RAB is downgraded from the negotiated QoS of the PDP
context, no PDP context modification is required since more RABs/RBs can be
allocated for the same service when more resources are available.
[0028] If all of the above steps are successfully executed, the MME 415
returns an activate PDP context accept message, (PDP type, PDP address, TI,
QoS negotiated, radio priority, and the like), to the WTRU 405 (step 440). At
this
point, the first RB associated with the PDP context and GPRS tunneling
protocol
(GTP) tunnel between the anchor node 420 and the eNodeB 410 are established
(steps 442, 444).
[0029] As shown by procedure 450 of Figure 4, for every new service
requested at the WTRU 405, a new RB/RAB needs to be established (step 452).
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The WTRU 405 sends a message to the eNodeB 410 to request a new RB for the
new service (step 454). A service related QoS request can be passed with the
message. The eNodeB 410 checks the availability of resources (step 456), and
may deny the request if there are not enough resources. The eNodeB 410
forwards the request to the MME 415 for a new RAB (step 458). Since the WTRU
405 knows the NSAPI from the first RAB establishment, (i.e., the RAB
established during the Primary PDP context activation), the MME 415 will know
to which PDP context the request should associate.
[0030] The MME 415 informs the anchor node 420 that there is a new RAB
established for a certain PDP context (step 460). The anchor node 420
allocates
the necessary resources for the service at the end of the tunnel, updates
charging
and routing information, and sends a response back to MME 415 (step 462).
[0031] The RAB assignment and RB setup procedures (steps 464, 466,468
and 470 are performed in a conventional manner. Steps 464, 466, 468 and 470
may be performed in parallel with steps 460 and 462, which can reduce delay.
The steps of procedure 450 are iterative whenever there is a new service
requested at step 452.
[0032] In accordance with another embodiment of the present invention,
Figure 5 shows the procedures for PDP context activation and RAB assignment
in an LTE system 500 including a WTRU 505, an eNodeB 510, an MME 515 and
an anchor node 520. In the proposed procedure, no additional secondary PDP
context activations are needed for multiple sets of services. Dynamic requests
of
new services are accommodated by RB establishments and releases between the
WTRU 505 and the eNodeB 510.
[0033] Referring to Figure 5, the WTRU 505 sends an activate PDP context
request message to the MME 515 (step 525). In the request, a list of NSAPI,
APN, services, and the corresponding QoS requirements are specified. Note that
different from a conventional PDP context activation procedure which gives one
NSAPI and one A.PN only, the proposed procedure will have a list of NSAPI,
services, and APNs to be negotiated and established in one PDP context
activation procedure. If different requests of services occur later on, no
additional
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PDP context activation procedures are required, thus limiting the signaling
between the WTRU 505 and the eNodeB 510.
[0034] Still referring to Figure 5, in step 530, the MME 530 validates the
activate PDP context request, selects at least one APN, maps the APN to the
anchor node 520, determines GTP TEIDs and a NSAPI list. The WTRU 505 lists
all of the services that need to be activated using the list of APNs. Each
service
is marked by a different NSAPI, and a QoS profile. In step 535, the MME 515
sends a create PDP context request message to the anchor node 520. In step
540,
for a valid PDP context request, the anchor node 520 will create a PDP entry.
A
different PDP is associated with each service requested. In this case, if all
the
services are provided via/by the same gateway, (i.e., anchor node 520), then
there
is one IP address=and multiple port numbers. Each port number is associated
with the service being activated. Additionally, in step 540, the anchor node
520
creates charging information for a valid PDP context request. Each service
will
be charged separately and according to different criterion. For example, video
calls may be charged differently than text messages. Therefore, each service
will
be have a different charge ID.
[0035] At this point, the PDP context activation procedure is completed at
the anchor node 520. The anchor node 520 then starts the acknowledgment
phase of the operation by sending a create PDP context response message back
to
the MME 515, (step 545) which ensures that the RAN, (e.g., the eNode B 510),
is
aware of multiple tunnels being activated (step 550). The MME sends the
information related to the number of services being activated and the
associated
ASAPI, PDP address, Gateway TEID, WTRU ID (temporary ID), so that each
tra.ffic flow is routed accordingly. The RAN, (e.g., the eNode B 510), then
activates a RAB for each service and maps each flow to the associated IDs
(step
555) to establish the tunnels (step 560), (direct tunnel or traditional GPRS
dual
tunnels, (RANAP and GTP)). In step 565, the MME 515 concludes the activation
procedures by informing the WTRU 505 that the activation process was a
success. The MME 515 sends a list of all of the successfully activated
services.
In case of a failure to activate a certain service, the MME 515 indicates the
failed
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service and the reason for the failure. In step 570, the WTRU 505 and/or the
RAN, (e.g., the eNodeB 510), may activate/deactivate the physical RBs/channels
based on the availabnlity of data flows to be transmitted.
[0036] For more services need to be established later, the above procedure
will be limited to RB setups between WTRU 505 and the eNodeB 510 only.
[0037] During the activation of PDP context, the RAN and CN negotiate
the QoS parameters for the PDP context, e.g., maximum bit rate, guaranteed bit
rate, maximum delay, etc. The QoS profile is then passed to RAN in the
immediate RAB assignment procedure. The QoS requirements of all the
R.ABs/R.Bs allocated under the PDP context should be within the QoS
restriction
of the PDP context.
[0038] - Figure 6 shows multiple PDP contexts that are established for
multiple PDNs in a wireless communication system 600. The system 600
includes a WTRU 605, an eNodeB 610, an MME 615, an anchor node 620 and
APNs 625A-625E. If a new service requires a new APN, and thus a new access
gateway, the MME 615 has to allocate a new tunnel between the eNodeB 610 and
the new access gateway. The WTRU 605 is likely to get a different IP address
from each PDN. Thus, a different PDP context is established. The procedures to
establish PDP context are the same as described above.
[0039] With the proposed PDP context procedure, one PDP context is
enough for multiple services of one IP address for the WTRU 605. Establishing
a
secondary PDP context can be optional, for example, if the operator wants to
bundle certain services under the secondary PDP context. The handling of the
secondary PDP context is the same as what it is done now.
[0040] Multiple R.ABs/RBs can be established and associated with the PDP
context. The eNodeB 610 should be able to allow for multiple radio bearers for
multiple streams as long as the bit rate and delay budget, (set during the PDP
context activation), is not violated. In case the request for additional
bearers
from the eNodeB violate the QoS restrictions, the eNodeB 610 informs the WTRU
605 that the existing request requires modification of the PDP context and/or
the
activation of the secondary PDP context. The number of the parallel flows
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allowed for a PDP context can be defined. If the WTRU 605 has exhausted the
allowed service, its request should be denied.
[0041] Currently, there is a one-to-one relationship between NSAPI, RAB,
and PDP context. In the packet domain, there is also a one-to-one relationship
with RB Identity. With the proposed change of the PDP context procedures, a
new mapping needs to be established. The meaning of NSAPI will remain the
same. In the WTRU 605, NSAPI identifies the PDP service access point (SAP).
In the MME 615 and the anchor node 620, NSAPI identifies the PDP context
associated with a mobility management (MM) context, which indicates what
state the WTRU 605 is in. The MM context has all the information related to
the
WTRU 605 while operating in the network, such as QoS, different security
information, and the like. The RAB ID should have the information of both the
NSAPI, (i.e., the PDP context the RAB is associated with), and a unique ID for
the RAB. Thus, each RAB is mapped to a PDP context. The method of how to
form the RAB ID is up to implementation. The RB ID can be the same as a RAB
ID.
[0042] Embodiments
1. In a long term evolution (LTE) communication system including a
wireless transmit/receive unit (WTRU), an evolved Node-B, a mobility
management entity (MME) and an anchor node, a method comprising:
(a) establishing a first radio bearer associated with packet data protocol
(PDP) context and a general packet radio service (GPRS) tunneling protocol
(GTP) between the anchor node and the evolved Node-B;
(b) the WTRU sending a message to the evolved Node-B to request a new
radio bearer (RB) for a new service;
(c) the evolved Node-B forwarding the message to the MME, wherein the
MME maps access point names (APNs) to the anchor node, determines GTP
tunnel endpoint identifiers (TEIDs) and a network layer service access point
identifier (NSAPI) list; and
(d) the MME informing the anchor node that there is a new radio access
bearer (RAB) established for a certain PDP context.
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2. The method of embodiment 1 wherein the anchor node allocates the
necessary resources for the service at the end of the tunnel, updates charging
and
routing information, and sends a response back to MME.
3. The method as in any one of embodiments 1 and 2 wherein a service
related quality of service (QoS) request is passed with the message.
4. The method as in any one of embodiments 1-3 wherein the evolved
Node-B checks for the availability of resources.
5. The method of embodiment 4 wherein the evolved Node-B denies the
message if there are not enough resources.
6. A long term evolution (LTE) communication system comprising:
(a) an evolved Node-B;
(b) a wireless transmit/receive unit (WTRU) configured to send a message
to request a new radio bearer (RB) for a new service;
(c) an anchor node configured to establish a first radio bearer between the
anchor node and the evolved Node-B, wherein the first radio bearer is
associated
with packet data protocol (PDP) context and a general packet radio service
(GPRS) tunneling protocol (GTP); and
(d) a mobility management entity (MME) configured to map access point
names (APNs) to the anchor node, determine GTP tunnel endpoint identifiers
(TEIDs) and a network layer service access point identifier (NSAPI) list, and
inform the anchor node that there is a new radio access bearer (RAB)
established
for a certain PDP context.
7. The system of embodiment 6 wherein the anchor node allocates the
necessary resources for the service at the end of the tunnel, updates charging
and
routing information, and sends a response back to MME.
8. The system as in any one of embodiments 6 and 7 wherein a service
related quality of service (QoS) request is passed with the message.
9. The system as in any one of embodiments 6-8 wherein the evolved
Node-B checks for the availability of resources.
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10. The system of embodiment 9 wherein the evolved Node-B denies the
message if there are not enough resources.
11. In a long term evolution (LTE) communication system including a
wireless transmit/receive unit (WTRU), an evolved Node-B, a mobility
management entity (MME) and an anchor node, a method comprising:
(a) the WTRU sending an activate packet data protocol (PDP) context
request message to the MME, the activate PDP context request message
including a list of network layer service access point identifiers (NSAPIs),
services and access point names (APNs) to be negotiated and established in a
single PDP context activation procedure;
(b) the MME validating the activate PDP context request and sending a
create PDP context request message to the anchor node;
(c) the anchor node creating a new PDP entry and charging identifier;
(d) the anchor node sending a create PDP context response message to the
MME;
(e) setting up radio access bearers (RABs) between the evolved Node-B and
the MME; and
(f) setting up radio bearers (RBs) between the WTRU and the evolved
Node-B.
12. The method of embodiment 11 wherein the MME maps APNs to the
anchor node, determines general packet radio service (GPRS) tunneling protocol
(GTP) tunnel endpoint identifiers (TEIDs) and a NSAPI list, and the MME
informs the anchor node that there is a new RAB established for a certain PDP
context.
13. The method of embodiment 12 wherein the anchor node allocates
the necessary resources for the service at the end of the tunnel.
14. The method as in any one of embodiments 11-13 wherein a service
related quality of service (QoS) request is passed with the activate packet
PDP
context request message to the MME.
15. The method as in any one of embodiments 11-14 wherein the
evolved Node-B checks for the availability of resources.
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16. A long term evolution (LTE) communication system comprising:
(a) an evolved Node-B;
(b) a wireless transmit/receive unit (WTRU) configured to send an activate
packet data protocol (PDP) context request message including a list of network
layer service access point identifiers (NSAPIs), services and access point
names
(APNs) to be negotiated and established in a single PDP context activation
procedure;
(c) an anchor node configured to receive a create PDP context request
message to the anchor node, to create a new PDP entry and charging identifier,
and send a create PDP context response message; and
(d) a mobility management entity (MME) configured to receive the create
PDP context response message.
17. The system of embodiment 16 wherein radio access bearers (RABs)
are set up between the evolved Node-B and the MME, and radio bearers (RBs)
are set up between the WTRU and the evolved Node-B.
18. The system of embodiment 17 wherein the MME maps APNs to the
anchor node, determines general packet radio service (GPRS) tunneling protocol
(GTP) tunnel endpoint identifiers (TEIDs) and a NSAPI list, and the MME
informs the anchor node that there is a new RAB established for a certain PDP
context.
19. The system of embodiment 18 wherein the anchor node allocates the
necessary resources for the service at the end of the tunnel.
20. The system as in any one of embodiments 16-19 wherein a service
related quality of service (QoS) request is passed with the activate packet
PDP
context request message to the MME.
21. The system as in any one of embodiments 16-20 wherein the evolved
Node-B checks for the availability of resources.
[0043] Although the features and elements of the present invention are
described in the preferred embodiments in particular combinations, each
feature
or element can be used alone without the other features and elements of the
preferred embodiments or in various combinations with or without other
features
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and elements of the present invention. The methods or flow charts provided in
the present invention may be implemented in a computer program, software, or
firmware tangibly embodied 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).
[0044] 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.
[0045] 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 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) module.
~ * *
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