Indian Patents
Title of Invention

METHOD, APPARATUS AND SYSTEM FOR KEY DERIVATION
Abstract A method, an apparatus and a system for key derivation are disclosed. The method includes the following steps: a target base station receives multiple keys derived by a source base station, where the keys correspond to multiple cells under control of the target base station; the target base station selects a key corresponding to the target cell after knowing a target cell that a user equipment (UE) wants to access. An apparatus for key derivation and a communications system are also provided.
Full Text

Field of the Invention
The present invention relates to the mobile communication field, and in particular, to a
method, an apparatus and a system for key derivation.
Background of the Invention
In a long term evolution (LTE) system in the prior art, if a user equipment (UE) in
connecting state detects that quality of signal in a source cell is poor, the base station of the
source cell (hereinafter referred as source base station) makes the following handover
preparations after receiving a measurement report from the UE. The source base station
derives a key_A according to a target cell's physical cell identifier (ID), sends the key_A to
the base station X of a target cell A (hereinafter referred as target base station), and sends a
handover command to the UE. If the UE cannot receive the handover command in case of
radio link failure (RLF), the UE re-selects a proper cell and initiates a radio resource
control (RRC) connection reestablishment procedure to resume the service.
In the technical solution in the prior art, when the base station of a target cell B that the
UE attempts to access through the connection reestablishment procedure is the same as the
base station of the target cell A, the UE derives a key_B by using the physical cell ID of the
target cell B, and encrypts messages that the UE sends to the base station X by using the
key_B; the base station X decrypts the messages sent from the UE by using the key_A
.according to context information of the UE. Thus, the keys used by the UE and the base
station X are inconsistent, which leads to a failure of communication between the UE and
the base station.


Summary of the Invention
Embodiments of the present invention provide a method, an apparatus and a system for
key derivation to solve the failure of communication between a UE that attempts to access a
target cell.
According to one aspect of the present invention, a method for key derivation is
provided, which includes:
receiving, by a target base station, multiple keys derived by a source base station,
where the multiple keys correspond to multiple cells under control of the target base
station;
receiving, by the target base station, a radio resource control (RRC) connection
reestablishment request from a User Equipment (UE); and
selecting, by the target base station, a key for being used in communication with
the UE, the selected key corresponding to the target cell that the UE requests to access.
According to the other aspect of the present invention, an apparatus for key derivation
is provided, which includes:
a first unit, configured to receive multiple keys derived by a source base station,
the multiple keys corresponding to multiple cells under control of a target base station,
wherein the first unit is further configured to receive a Radio Resource Control, RRC,
connection reestablishment request message from a User Equipment, UE; and
a second unit, configured to select a key for being used in communication with the
UE, the selected key corresponding to the target cell that the UE requests to access.
According to another aspect of the present invention, a communications system
provided in an embodiment of the present invention includes the key deriving apparatus
provided in an embodiment of the present invention and the UE that communicates with the
key deriving apparatus.
In exemplary embodiments of the present invention, the UE and the network apparatus
derive keys by using the same key derivation parameters. Thus, the UE and the network


apparatus derive the same key, which guarantees normal communication between the UE
and the network apparatus, reduces the call drop rate, and brings a better user experience.
Brief Description of the Drawings
FIG 1 is a flowchart of a method for key derivation according to a first exemplary
embodiment of the present invention;
FIG 2 is a flowchart of a method for key derivation according to a third exemplary
embodiment of the present invention;
FIG 3 is a flowchart of a method for key derivation according to a fourth exemplary
embodiment of the present invention;
FIG 4 is a schematic diagram illustrating an apparatus for key derivation according to a
fifth exemplary embodiment of the present invention;
FIG 5 is a schematic diagram illustrating an apparatus for key derivation according to a
sixth exemplary embodiment of the present invention;
FIG 6 is a schematic diagram illustrating an apparatus for key derivation according to a
seventh exemplary embodiment of the present invention; and
FIG 7 is a schematic diagram illustrating a communications system according to an
eighth exemplary embodiment of the present invention.
Detailed Description of the Invention
The technical solution of the present invention is hereinafter described in detail with
reference to the accompanying drawings. It is evident that the embodiments are exemplary
only and the present invention is not limited to such embodiments. Other embodiments that
those skilled in the art obtain based on embodiments of the present invention also fall in the
scope of protection of the present invention.
In the method for key derivation in an exemplary embodiment of the present invention,
when the target base station receives at least one key that is derived according to the target


base station identifier (ID) and/or target cell's physical cell ID (PCI), upon reception of an
RRC connection reestablishment request from a UE, the target base station selects a Key_A
and provides the UE with the target base sation ID or target cell's physical cell ID needed
for deriving the Key_A. The selected Key_A may be derived according to the target base
station ID, or according to the target cell's physical cell ID corresponding to the cell where
the UE is located or according to the physical cell ID carried in the RRC connection
reestablishment request. Thus, the key derived by the UE is the consistent with the key
determined by the target base station, which guarantees normal communication between
the UE and the base station, reduces the call drop rate, and brings a better user experience.
In exemplary embodiments of the method for key derivation, the UE initiates a
connection reestablishment procedure, and derives a key according to the target base
station ID or target cell's physical cell ID provided by the target base station. Thus, the key
derived by the UE is consistent with the key used by the target base station, which
guarantees normal communication between the UE and the eNodeB, reduces the call drop
rate, and brings a better user experience.
In the prior art, the process of key derivation includes a primary derivation process in
which a key KeNB* is derived according to the target cell's physical cell ID and a
secondary process in which a key KeNB** is derived according to the KeNB* derived in
the primary derivation process. The process of key derivation carried out by the UE and the
network apparatus in embodiments of the present invention is the primary derivation
process. In the method for key derivation in an embodiment of the present invention, the
UE and the network apparatus derive the same KeNB* in the primary derivation process.
Thus, the UE and the network apparatus also derive the same KeNB** in the secondary
derivation process, so that the UE and the network apparatus can maintain normal
communications by using the KeNB**. It is understandable to those skilled in the art that
the method for key derivation described in exemplary embodiments of the present


I
invention can be combined with the method involved in the secondary derivation process in
the prior art, a detailed description is omitted here.
FIG 1 is a flowchart of a method for key derivation according to the first exemplary
embodiment. As shown in FIG 1, a source base station is a network apparatus (for example,
eNode B) that currently serves a UE, and the target base station is another network
apparatus that the source base station selects to serve the UE. The method includes the
following steps:
5101. The UE sends a measurement report to the source base station.
5102. The source base station makes a handover decision and derives keys according to
the obtained target cell's physical cell ID and the target base station ID respectively.
In this step, it is assumed that the key derived according to the target cell's physical cell
ID is KeNB* 1 and the key derived according to the target base station ID is KeNB*2.
It is understandable to those skilled in the art that various key derivation algorithms and
methods in the prior art are applicable to the key derivation process in this step and are not
further described.
SL03. The source base station sends the KeNB*l and KeNB*2 to the target base
tstation.
In this step, the keys may be carried in an access stratum message sent through an X2
interface between the source base station and the target base station. For example, the keys
are carried in reserved fields or extended fields in an existing message (for example, a
handover request) or a new message. The keys may also be carried in a message sent by an
SI interface between the source base station and a mobility management entity (MME),
and the MME provides the received keys for the target base station.
5104. The target base station stores the received key, and sends a handover request
Acknowledgement (ACK) message.
5105. The source base station sends a handover command to the UE.


If the UE receives the handover command, the UE executes S106' (not shown in the
Figure). That is, the UE derives a key KeNB*1 according to the target cell's physical cell
ID. The KeNB* 1' is consistent with the KeNB*1 stored in the target base station in terms of
derivation algorithms and parameters, and thus the KeNB*1' is consistent with the
KeNB*1.
If an Radio Link Failure (RLF) or handover failure occurs, the connection
reestablishment procedure initiated by the UE may include the following steps:
5106. The UE sends an RRC connection reestablishment request to the target base
station.
5107. If the target base station receives the connection reestablishment request and
finds that the key corresponding to the UE is stored in the target base station, the target base
station selects the KeNB*2, and sends an RRC connection reestablishment message to the
UE.
In this step, the target base station may search for the context information in the target
base station according to the UE information so as to find whether the key corresponding to
the UE is stored in the target base station. The process of selecting the KeNB*2 by the
target base station is a secondary derivation process performed by the target base station
•according to the KeNB*2. If, after searching for the context information, the target base
station finds that the key corresponding to the UE is not stored in the target base station, the
target base station may establish a communication with the UE to obtain the context
information of the UE and select some of the context information for storing, which does
not affect the implementation of the present invention.
5108. The UE receives the RRC connection reestablishment message, and derives a key
KeNB*2' according to the obtained target base station ID.
The KeNB*2' in this step is consistent with the KeNB*2 stored in the target base station
in terms of derivation algorithms and parameters, and thus the KeNB*2' is consistent with
the KeNB*2. The KeNB*2' derived by the UE is used in the secondary derivation process.


In this step, the target base station ID obtained by the UE may come from a system
broadcast message. That is, before starting the connection reestablishment procedure or
after receiving the RRC connection reestablishment message, the UE reads the target base
station ID carried in the system broadcast message. The target base station ID obtained by
the UE may also come from the RRC connection reestablishment message. That is, the
RRC connection reestablishment message that the target base station sends to the UE in
S107 carries a target base station ID, and the UE reads the target base station ID and derives
a key in S108, making it unnecessary to read the system broadcast message. In addition, the
target base station ID obtained by the UE may come from other messages that the target
'base station sends to the UE.
It is understandable to those skilled in the art that a cell global identifier (CGI) includes
information about the target base station ID. Thus, the message that carries the target base
station ID may also be the message that carries the CGI. The receiver reads information
about the target base station ID from the CGI, and then uses the target base station ID.
In this embodiment, the source base station sends the two derived keys to the target
base station. If the UE succeeds in handover, the UE communicates with the target base
station by using the key derived according to the target cell's physical cell ID. When the
connection reestablishment procedure is performed in case of an RLF or handover failure
.of the UE, the UE communicates with the target base station by using the key derived
according to the target base station ID. Thus, normal communication between the UE and
the network apparatus is guaranteed. The method provided in this embodiment can reduce
the call drop rate and bring a better user experience without changing the air interface.
The second exemplary embodiment is similar to the first embodiment except for the
following difference: The source base station drives a key according to the obtained target
base station ID instead of the target cell's physical cell ID, and sends the derived KeNB*2
to the target base station; the target base station carries a target base station ID in the
handover command sent to the UE, so that the UE can derive the KeNB*2' according to the


target base station ID after receiving the handover command. Thus, the KeNB*2' is
consistent with the KeNB*2. In addition, if the UE initiates a connection reestablishment
procedure due to failure to receive the handover command, the target base station carries
the target base station ID in the RRC connection reestablishment message sent to the UE or
carries the target base station ID in the system broadcast message, so that the UE derives
the KeNB*2' according to the target base station ID read from the RRC connection
reestablishment message or system broadcast message. Thus, the KeNB*2' is the consistent
as the KeNB*2.
In this embodiment, the UE and the network apparatus derive keys by using the target
base station ID as the parameter. Thus, the keys derived by the UE and the network
apparatus are consistent, which guarantees normal communication between the UE and
the network apparatus, reduces the call drop rate, and brings a better user experience.
FIG 2 is a flowchart of a method for key derivation according to the third exemplary
embodiment of the present invention. As shown in FIG 2, the source base station is a
network apparatus (for example, source eNodeB) that currently serves the UE, and the
target base station is another network apparatus (for example, target eNode B) that the
source base station selects to serve the UE. The method includes the following steps:
5201. The UE sends a measurement report to the source base station.
5202. The source base station makes a handover decision, searches for all target cells'
.physical cell IDs corresponding to the source base station according to the obtained target
base station ID, and derives keys according to the target cells' physical cell IDs
respectively.
In this step, it is assumed that the target base station has three cells; that is, there are
three target cells' physical cell IDs corresponding to the target base station ID, namely,
Ce111, Ce1112, and Ce113. Thus, three keys are derived, represented by KeNB*1, KeNB*2,
and KeNB*3.


It is understandable to those skilled in the art that various key derivation algorithms and
methods in the prior art are applicable to the key derivation process in this step and are not
further described.
5203. The source base station sends the KeNB*1, KeNB*2 and KeNB*3 to the target
base station.
In this step, the keys may be carried in an access stratum message sent through the X2
interface between the source base station and the target base station. The keys may be
carried in reserved fields or extended fields in an existing message (for example, a
handover request) or a new message. The keys may also be carried in a message sent by the
S1 interface between the source base station and the MME, and the MME provides the
.received keys for the target base station. In addition, the source base station may carry
multiple keys in one message for transmission so as to save resources and improve the
transmission efficiency. Furthermore, the source base station may also carry multiple keys
to different messages for transmission so as to improve the flexibility of transmission.
5204. The target base station stores the received keys, and sends a handover request
ACK message.
5205. The source base station sends a handover command to the UE.
If the UE receives the handover command and obtains a target cell's physical cell ID,
for example Ce111, the UE executes S206' (not shown in the figure). That is, the UE derives
a KeNBT according to the Ce111's physical cell ID. The KeNB*1 is consistent with the
KeNB*1 in the target base station in terms of derivation algorithms and parameters, and
thus the KeNBT is consistent with the KeNB*1.
If the UE cannot receive the handover command in case of an RLE, the connection
reestablishment procedure initiated by the UE includes the following steps:
5206. The UE sends an RRC connection reestablishment request to the target base
station.


5207. The target base station receives the connection reestablishment request, and
learns'that a physical cell ID of the cell which the UE requests to access is the ID of Cell2
"of the target base station. The target base station uses the KeNB*2 corresponding to the
Cell2, and sends an RRC connection reestablishment message to the UE.
5208. The UE receives the RRC connection reestablishment message, and derives a
KeNB*2' according to the Cell2.
In this step, the KeNB*2' is consistent with the KeNB*2 stored in the target base station
in terms of derivation algorithms and parameters, and thus the KeNB*2' is consistent with
the KeNB*2.
In this step, the target cell's physical cell ID obtained by the UE may come from a
physical layer ID broadcasted in the system or from the RRC connection reestablishment
message. The target base station may carry a target cell's physical cell ID in the RRC
connection reestablishment message sent to the UE in step S207, and the UE reads the
target cell's physical cell ID and derives a key in S208. The target cell's physical cell ID
obtained by the UE may also come from other messages that the target base station sends to
the UE.
In this embodiment, the source base station sends all the keys derived according to the
target cells' physical cell IDs to the target base station, so that the target base station may
select a key for being used in communications with the UE according to a cell that the UE
wants to access. Thus, the success rate of UE access to new cells is increased and may
reach 100%. The source base station may also select some of key(s) and send the key(s) to
the target base station according to some conditions; for example, it may only send key(s)
derived according to the target cell(s)' physical cell ID(s) of cell(s) with a higher priority.
The source base station may also derive key(s) according to some conditions; for example,
it may only derive key(s) according to the target cell(s)' physical cell ID(s) of cell(s) with a
lower priority and send the derived key(s) to the target base station. Thus, the success rate


of UE access is increased and the amount of information transmitted by the source base
station is reduced, but the success rate of UE access is smaller than 100%.
In the method provided in the preceding exemplary embodiment of the present
invention, if an RLF occurs when the UE accesses a cell al of a target base station A, the
UE can access a cell a2 of the target base station through the connection reestablishment
procedure. It should be noted that the measurement report sent to the source base station by
the UE carries information of multiple accessible target base stations. Thus, the key
derivation process of the source base station may be specific to multiple cells under control
of multiple target base stations. However, during the key transmission, the keys that the
source base station sends to the target base station A may include only keys of different
cells under control of the target base station A. Thus, the preceding embodiment exemplary
of the present invention is also applicable to the process of UE handover between different
target base stations.
FIG 3 is a flowchart of a method for key derivation according to the fourth exemplary
embodiment of the present invention. As shown in FIG 3, the source base station is a
network apparatus (for example, source eNodeB) that currently serves the UE, and the
target base station is another network apparatus (for example, target eNodeB) that the
source base station selects to serve the UE. The method includes the following steps:
S301. The UE sends a measurement report to the source base station.
S3 02. The source base station makes a handover decision, and derives a key according
to the obtained target cell's physical cell ID.
In this step, it is assumed that the key derived according to the target celll's physical
cell ID is KeNB*l. Various key derivation algorithms and methods in the prior art are
applicable to the key derivation process in this step, and are not further described.
S3 03. The source base station sends the KeNB* 1 to the target base station.
S304. The target base station stores the received key, and sends a handover request
ACK message.


5305. The source base station sends a handover command to the UE.
If the UE cannot receive the handover command in case of an RLF, the connection
reestablishment procedure initiated by the UE may include the following steps:
5306. The UE sends an RRC connection reestablishment request to the target base
'station.
5307. After the target base station receives the connection reestablishment request, the
target base station sends an RRC connection reestablishment message that carries the Celll
in the handover request, and derives a KeNB* 1 by using the Celll.
5308. The UE receives the RRC connection reestablishment message, and derives a
KeNB*1 by using the Celll. Thus, the KeNB*l' is consistent with the KeNB*l.
In this embodiment, the target base station may use the key already stored in the target
base station without re-deriving a key. The UE derives a key according to the target cell's
physical cell ID provided by the target base station. Thus, the keys used by the UE and the
.network apparatus are the same, which guarantees normal communication between the UE
and the network apparatus, reduces the call drop rate, and brings a better user experience.
It is understandable to those skilled in the art that this embodiment is applicable not
only to the process of UE handover between different cells under control of the same target
base station, but also to the process of UE handover between different target base stations.
In addition, it is understandable to those skilled in the art that the network apparatus and
the UE in this embodiment may reach an agreement in advance on one or more of the
following aspects: method for key derivation, method for selecting key derivation
parameters, and method for sending key derivation parameters. In this case, the network
apparatus derives a key according to the agreed method, and sends the needed parameters
to the UE, while the UE receives the needed parameters and derives a key according to the
agreed method. The network apparatus and the UE may also determine the preceding
methods through negotiations. The specific negotiation method does not affect the


implementation of the present invention and technical solution, and therefore is not further
described.
FIG 4 illustrates an apparatus for key derivation according to the fifth embodiment of
the present invention. The apparatus includes:
a receiving unit 41, configured to receive at least one key, where the key is derived
according to a target base station ID and/or a target cell's physical cell ID;
a determining unit 42, configured to receive an RRC reestablishment request from
a UE, and select a Key_A, where the Key_A may be derived according to the target
base station ID, or according to the target cell's physical cell ID corresponding to the
cell where the UE is located, or be derived according to a physical cell ED carried in
the RRC reestablishment request; and
a sending unit 43, configured to send the target base station ID or target cell's
physical cell ID required for deriving the Key_A.
FIG 5 illustrates an apparatus for key derivation according to the sixth exemplary
.embodiment of the present invention. The apparatus includes:
a triggering unit 51, configured to initiate a connection reestablishment procedure,
and trigger a receiving unit 52;
the receiving unit 52, configured to receive the target base station ID and/or target
cell's physical cell ID when being triggered by the triggering unit 51; and
a key deriving unit 53, configured to derive a key according to the target base
station ID or target cell's physical cell ID received by the receiving unit 52.
FIG 6 illustrates an apparatus for key derivation according to the seventh exemplary
embodiment of the present invention. The apparatus includes a first unit 61 and a second
unit 62.
The first unit 61 is configured to receive multiple keys derived by a source base station,
where the multiple keys correspond to multiple cells under control of a target base station.
The second unit 62 is configured to select a key corresponding to a target cell after knowing


the target cell that the UE requests to access. Further, the key corresponding to the target
cell that the second unit 62 selects is derived by the source base station according to the
target cell's a physical cell ID.
The keys corresponding to the cells under control of the target base station that the first
unit 61 receives are derived by the source base station according to cell's physical cell IDs
of the target base station. The source base station may send all the keys that are derived
according to the target cells' physical cell IDs to the target base station, so that the target
base station may select a key for being used in communications with the UE according to
the cell that the UE wants to access. Thus, the success rate of UE access to new cells is
100%. The source base station may also select a key and send the key to the target base
station according to some conditions; for example, it may only send a key derived
according to physical cell ID(s) of target cell(s) with a higher priority. The source base
station may also derive a key according to some conditions; for example, it may only derive
a key according to physical cell ID(s) of target cell(s) with a low priority, and send the
key(s) to the target base station. Thus, the success rate of UE access is increased and the
amount of information transmitted by the source base station is reduced, but the success
rate of UE access is lower than 100%.
The first unit 61 is further configured to receive an RRC connection reestablishment
request from the UE.
The apparatus for key derivation may further include a third unit 63, which is
configured to send the target cell's physical cell ID to the UE.
Optionally, the apparatus for key derivation in this embodiment may be a base station.
FIG 7 illustrates a communications system in the eighth exemplary embodiment of the
present invention. The communications system includes an apparatus 71 for key derivation
according to the seventh exemplary embodiment and a UE 72 that communicates with the
r
apparatus 71.


The communications system may further include an MME 73, which is configured to:
receive a target cell physical ID that the apparatus 71 sends to the UE, and forward the
target cell physical ID to the UE.
Further, the apparatus 71 in the communications system may be used as the target base
station of the UE.
The ninth exemplary embodiment of the present invention also provides a
communications system. The communications system includes a UE and a network
apparatus.
The UE is configured to derive a key according to the received target base station ID or
target cell's physical cell ID.
The network apparatus is configured to: select a Key_A from at least one key that is
derived according to the target base station ID and/or target cell's physical cell ID
according to the received RRC reestablishment request, and send the target base station ID
and target cell's physical cell ID needed for deriving the Key_A.
The communications system may further include an Mobility Management Entity
(MME), which is configured to forward the information about communication between the
network apparatus and the UE. The MME forwards the target base station ID or target cell's
physical cell ID sent from the network apparatus to the UE.
It is understandable to those skilled in the art that all or part of the steps in the preceding
embodiments may be implemented by hardware instructed by a program. The program may
be stored in a computer readable storage medium. When the program is executed, the
processes of the preceding method embodiments are involved. The preceding storage
medium may be a magnetic disk, a compact disk (CD), a read-only memory (ROM), or a
random access memory (RAM).
In embodiments of the present invention, the key deriving apparatus and
communications system can ensure that the UE and the network apparatus use the same key,


which guarantees normal communication between the UE and the network apparatus,
reduces the call drop rate, and brings a better user experience.
Although the invention has been described through several exemplary embodiments,
the invention is not limited to such embodiments. It is apparent that those skilled in the art
can make various modifications and variations to the invention without departing from the
scope of the invention. The invention is intended to cover the modifications and variations
provided that they fall in the scope of protection defined by the claims or their equivalents.


WE CLAIM:
1. A method for key derivation, comprising:
receiving, by a target base station, multiple keys derived by a source base station,
wherein the multiple keys correspond to multiple cells under control of the target base
station;
receiving, by the target base station, a radio resource control (RRC) connection
reestablishment request from a User Equipment (UE); and
selecting, by the target base station, a key for being used in communication with the UE,
the selected key corresponding to a target cell that the UE requests to access.
2. The method according to claim 1, wherein the multiple keys are derived according to
physical cell identifiers, IDs, of cells under control of the target base station.
3. The method according to claim 1 or 2, wherein
the multiple keys are all or part of the keys derived by the source base station according
to the physical cell IDs of all cells under control of the target base station, the part of the
keys being selected and sent to the target base station by the source base station according
to a preset condition; or
the multiple keys are derived by the source base station according to the physical cell
IDs of cells with higher priorities of the target base station.
4. The method according to claim 1, wherein the receiving, by the target base station,
the multiple keys sent by the source base station comprises:
receiving, by the target base station, an access stratum message comprising the multiple
keys sent by the source base station; or


receiving, by the target base station, a message by an S1 interface, the message
comprising the multiple keys sent by a Mobility Management Entity, MME, wherein the
multiple keys are provided for the MME by the source base station.
5. The method according to claim 1, further comprising:
sending, by the target base station, a target cell's physical cell ID to the UE.
6. The method according to claim 5, wherein the sending, by the target base station, the
target cell's physical cell ID to the UE comprises:
sending, by the target base station, system broadcast comprising the target cell's
physical cell ID to the UE; or
sending, by the target base station, an RRC connection reestablishment message
comprising the target cell's physical cell ID to the UE.
7. An apparatus, in a base station functioning as a target base station for a User
Equipment (UE), comprising:
a first unit, configured to receive multiple keys derived by a source base station, the
multiple keys corresponding to multiple cells under control of a target base station wherein
the first unit is further configured to receive a Radio Resource Control, RRC, connection
reestablishment request message from the UE; and
a second unit, configured to select a key for being used in communication with the UE,
the selected key corresponding to a target cell that the UE requests to access.
8. The apparatus according to claim 7, wherein the multiple keys are derived according
to physical cell identifiers, IDs, of the cells under control of the target base station.
9. The apparatus according to claim 7 or 8, wherein
the multiple keys are all or part of the keys derived by the source base station according
to the physical cell IDs of all cells under control of the target base station; wherein the part


of the keys are selected and sent to the target base station by the source base station
according to a preset condition; or
the multiple keys are derived by the source base station according to the physical cell
IDs of cells with a priority of the target base station.
10. The apparatus according to claim 7, wherein the key corresponding to the target cell
is derived by the source base station according to a target cell's physical cell ID.
11. The apparatus according to claim 7, further comprising:
a third unit, configured to send a target cell's physical cell ID to the UE.
12. An apparatus, in a base station functioning as a source base station for a User
Equipment (UE), comprising:
means for deriving multiple keys corresponding to multiple cells under control of a
target base station; and
means for send the multiple keys to the target base station.
13. The apparatus according to claim 12, wherein the multiple keys are derived
according to physical cell IDs of cells under control of the target base station.
14. The apparatus according to claim 12, wherein the transmitter is configured to send
the multiple keys in a handover request through an X2 interface.
15. A communications system, comprising the apparatus for key derivation according
to any one of claims 7 to 11, and a User Equipment communicating with the apparatus for
key derivation.



A method, an apparatus and a system for key derivation are disclosed. The method
includes the following steps: a target base station receives multiple keys derived by a
source base station, where the keys correspond to multiple cells under control of the target
base station; the target base station selects a key corresponding to the target cell after
knowing a target cell that a user equipment (UE) wants to access. An apparatus for key
derivation and a communications system are also provided.

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Patent Number 278996
Indian Patent Application Number 4270/KOLNP/2010
PG Journal Number 02/2017
Publication Date 13-Jan-2017
Grant Date 06-Jan-2017
Date of Filing 12-Nov-2010
Name of Patentee HUAWEI TECHNOLOGIES CO., LTD.
Applicant Address HUAWEI ADMINISTRATION BUILDING, BANTIAN, LONGGANG DISTRICT, SHENZHEN, GUANGDONG 518129, P.R. CHINA
Inventors:
# Inventor's Name Inventor's Address
1 HUANG, MIN HUAWEI ADMINISTRATION BUILDING, BANTIAN, LONGGANG DISTRICT, SHENZHEN, 518129, GUANGDONG, P.R. CHINA
2 CHEN, JING HUAWEI ADMINISTRATION BUILDING, BANTIAN, LONGGANG DISTRICT, SHENZHEN, 518129, GUANGDONG, P.R. CHINA
3 ZHANG, AIQIN HUAWEI ADMINISTRATION BUILDING, BANTIAN, LONGGANG DISTRICT, SHENZHEN, 518129, GUANGDONG, P.R. CHINA
4 LIU, XIAOHAN HUAWEI ADMINISTRATION BUILDING, BANTIAN, LONGGANG DISTRICT, SHENZHEN, 518129, GUANGDONG, P.R. CHINA
PCT International Classification Number H04W 36/08
PCT International Application Number PCT/CN2009/072322
PCT International Filing date 2009-06-17
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 200810067995.8 2008-06-23 China