Title of Invention

METHOD OF CONTROLLING TRANSMIT POWER IN WIRELESS COMMUNICATION SYSTEM

Abstract A method of controlling a transmit power includes determining a power control parameter of an assigned timeslot, wherein the value of the power control parameter is a default value if the assigned timeslot is assigned with no power control parameter and the valae of the power control parameter is the current value if the assigned timeslot is already used by the mobile station and determining the transmit power on an uplink channel.
Full Text Description
METHOD OF CONTROLLING TRANSMIT POWER IN
WIRELESS COMMUNICATION SYSTEM
Technical Field
The present invention relates to wireless communication and, in particular, to a
method of determining a transmit power on an uplink channel in a wireless commu-
nication system such as a general packet radio service (GPRS) system.
Background Art
The GSM (Global System for Mobile communication) is a radio technology which
has been developed as a system for standardizing radio communication systems in
Europe and which has widely been deployed all over the world. The GPRS (General
Packet Radio Service) is introduced to provide a packet switched data service in a
circuit switched data service provided from the GSM. The EDGE (Enhanced Data Rate
for GSM Evolution) employs the 8-PSK (Phase Shift Keying) instead of the GMSK
(Gaussian Minimum Shift Keying) employed in the GSM. The EGPRS (Enhanced
General Packet Radio Service) represents the GPRS using the EDGE.
The physical channel dedicated to GPRS/EGPRS traffic is called Packet Data
Channel (PDCH). Logical channels such as Packet Common Control Channel
(PCCCH), Packet Data Traffic Channel (PDTCH) and Packet Associated Control
Channel (PACCH) are mapped to the PDCH. The PCCCH is used for control signaling
necessary for initiating packet transfer. The PDTCH is used to transmit user data. The
PACCH is used for dedicated signaling.
Time division multiplex access (TDMA) scheme is applied in GSM/GPRS/EDGE
systems. In TDMA scheme, each mobile station in a cell transmits and receives circuit
switched data and/or packet switched data through assigned timeslots. One to eight
timeslots can be allocated to a mobile station per TDMA frame. Timeslots are shared
by the active users, and uplink and downlink timeslots are allocated separately.
Hereinafter, downlink means communication from a network to a mobile station, and
uplink means communication from a mobile station to a network. In GPRS/EDGE
system, users can share a single timeslot simultaneously with several users in a cell. A
single user may transmit and receive data over multiple timeslots simultaneously.
The power control is necessary to mitigate co-channel interference in a wireless com-
munication system. Keeping co-channel interference levels low can result in higher
throughput over a cell, potentially increasing cell's capacity. Effective power control
ensures that timeslots used for GSM/GPRS/EDGE system do not cause unacceptable
levels of interference to timeslots used for voice calls in co-channel neighbor cells.

Inadequate power control can cause high error rates or, at worst, broken radio con-
nections which in known as temporary block flows (TBFs). Power control errors may
increase packet delays and decrease user throughputs, thus causing service de-
gradation.
Uplink power control mechanisms allow a network to tune uplink transmit power
used by each mobile station transmitting uplink data blocks. Uplink power control
provides an additional important benefit: transmit power used by each mobile station
can be reduced to levels adequate to achieve proper link performance and transmit
power can be kept as low as possible without sacrificing link throughput, giving users
peak link performance without unnecessarily draining the mobile station's battery.
Disclosure of Invention
Technical Problem
The present invention provides a method of controlling a transmit power when a new
timeslot is allocated or a used timeslot is updated.
Technical Solution
In an aspect, a method of controlling a transmit power at a mobile station in a
wireless communication system is provided. The method includes determining a power
control parameter of an assigned timeslot, wherein the value of the power control
parameter is a default value if the assigned timeslot is assigned with no power control
parameter and the value of the power control parameter is the current value if the
assigned timeslot is already used by the mobile station and determining the transmit
power Pup on an uplink channel from the following equation:

where C0 is a power offset, CCH is the power control parameter, r is a system
parameter, L is a normalized received signal level at the mobile station and PMAX is the
maximum allowed transmit power in a cell.
In another aspect, a method of controlling a transmit power at a mobile station during
handover in a wireless communication system is provided. The method includes
receiving a handover command message from a network to command the mobile
station to leave a current cell and change to a new cell, the handover command
message comprising radio resources assigned for packet-switched (PS) services in the
new cell, the radio resources comprising information on at least one assigned timeslot,
determining a power control parameter of an assigned timeslot as a default value if the
assigned timeslot is assigned with no power control parameter and determining the
transmit power Pup on an uplink channel from the following equation:


[14] where C0 is a power offset, CCH is the power control parameter, r is a system
parameter, L is a normalized received signal level at the mobile station and PlVIAX is the
maximum allowed transmit power in a cell.
[15] In still another aspect, a mobile station includes a RF (Radio Frequency) unit for
transmitting radio signals using a transmit power, a memory configured to store a
default value for a power control parameter and a processor coupled to the RF unit and
the memory, and configured to determine a power control parameter of an assigned
timeslot, wherein the value of the power control parameter is the default value if the
assigned timeslot is assigned with no power control parameter and the value of the
power control parameter is the current value if the assigned timeslot is already used by
the mobile station and determine the transmit power Pup from the following equation:

[ 17] where C0 is a power offset, CCH is the power control parameter, r is a system
parameter, L is a normalized received signal level at the mobile station and PMAX is the
maximum allowed transmit power in a cell.
Advantageous Effects
[18] When a mobile station is assigned a timeslot or updates power and/or timing advance
for uplink transmission, the mobile station can stably control a transmit power of a
timeslot.
Brief Description of the Drawings
[19] FIG. 1 is a block diagram illustrating a wireless communication system.
[20] FIG. 2 is a block diagram showing elements of a mobile station.
[21] FIG. 3 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with an embodiment of the present invention.
[22] FIG. 4 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with another embodiment of the present invention.
[23] FIG. 5 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[24] FIG. 6 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[25] FIG. 7 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[26] FIG. 8 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[27] FIG. 9 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.

Mode for the Invention
[28] FIG. 1 is a block diagram illustrating a wireless communication system. This shows a
network based on the GSM (Global System for Mobile communication)/GPRS
(General Packet Radio Service). The wireless communication systems are widely used
to provide a variety of communication services of voice, packet data, and so on.
[29] Referring to FIG. 1, a mobile station (MS) 10 refers to a communication instrument
carried by a user and may also be called other terms such as a UE (User Equipment), a
UT (User Terminal), a SS (Subscriber Station), and a wireless device. A base station
(BS) 20 includes a base transceiver station (BTS) 22 and a base station controller
(BSC) 24. The BTS 22 communicates with the MS 10 in a cellular area through a radio
interface and a synchronization function with the MS 10. The BSC 24 interfaces at
least one BTS 22 with a mobile switching center (MSC) 30. The BS 20 may be called
as a base station subsystem, a Node-B, and an access point.
[30] The MSC 30 connects the BS 20 to a different kind of network such as the PSTN
(Public Switching Telephone Network) 65 or the PLMN (Public Land Mobile
Network) through the GMSC (Gateway MSC) 60. A VLR (Visitor Location Register)
40 stores temporary user data, which includes information on the roaming of all the
MSs 10 in a service area of the MSC 30. An FILR (Home Location Register) 50
includes information on all the subscribers in the home networks. An SGSN (Serving
GPRS Support Node) 70 takes charge of mobility management of the subscribers. A
GGSN (Gateway GPRS Data Network) 80 routs a packet at the current position of the
MS 10 to interface the MS with an external packet data network such as PDN (Public
Data Network) 85.
[31] A temporary block flow (TBF) is a logical connection offered by two Medium
Access Control (MAC) entities so as to support the unidirectional transfer of Radio
Link Control (RLC) Protocol Data Unit (PDU) on basic physical subchannels. The
TBF is not provided in a packet idle mode. In the packet idle mode, any radio resource
on a packet data physical channel is not assigned to the MS. At least one TBF is
provided in a packet transfer mode. In the packet transfer mode, radio resources on one
or more packet data physical channels for the transfer of packet data are assigned to the
MS. The MAC-idle state means a MAC-control-entity state where no basic physical
subchannel is assigned. A Temporary Row Identity (TFT) is assigned to each TBF by
the network. The MS assumes that the TFI value is unique among concurrent TBFs in
the same direction (uplink or downlink) on all Packet Data Channels (PDCHs) used for
the TBFs. The same TFI value may be used concurrently for TBFs on other PDCHs in
the same direction and for TBFs in the opposite direction.
[32] FIG. 2 is a block diagram showing elements of a mobile station. A mobile station

includes a processor 51, memory 52, a RF unit 53, a display unit 54, and a user
interface unit 55. The memory 52 is coupled to the processor 51 and stores a MS
operating system, applications and general files. The display unit 54 displays various
pieces of information of the MS and may employ well-known devices such as a Liquid
Crystal Display (LCD) or an Organic Light Emitting Diode (OLED). The user
interface unit 55 may consist of a combination of well-known user interfaces such as a
keypad and a touch screen. The RF unit 53 is coupled to the processor 51 and transmits
radio signals.
[33] The processor 51 implements functions of determining a transmit power. The
memory stores a power control parameter and the processor 51 determines the transmit
power using based on the power control parameter. The RF unit transmits radio signals
using the determined transmit power.
[34] FIG. 3 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with an embodiment of the present invention. This may be uplink access
from a mobile station to a network or may also be called random access procedure.
[35] Referring to FIG. 3, a mobile station sends a packet channel request message to the
network for radio access (SI 10). The packet channel request message may be a
message to request radio access. The mobile station requests allocation of radio
resources to the network for uplink transmission. The packet channel request message
can be transmitted on RACH (Random Access Channel) or PRACH (Packet Random
Access Channel). If the EGPRS is supported, the packet channel request message may
be an EGPRS channel request message. The mobile station can re-transmit the packet
channel request message by a predetermined number when there is no response from
the network after a predetermined time passes. If the mobile station does not receive
any response, regarding the packet uplink assignment message, from the network, it
results in random access failure.
[36] The network sends a packet uplink assignment message to the mobile station in
response to the packet channel request message (S120). The packet uplink assignment
message is a response of the network with respect to the radio access request by the
mobile station. The packet uplink assignment message can be transmitted on PCCCH
(Packet Common Control Channel) or PACCH (Packet Associated Control Channel).
The packet uplink assignment message can include information on radio resources,
which are required by the mobile station for uplink transmission. In the GSM/GPRS
system, the radio resources may be a timeslot. Alternatively, the radio resources may
be a radio block. In the GPRS system, one frame is comprised of eight timeslots, and a
radio block is comprised of four consecutive timeslots belonging to different frames.
[37] The mobile station determines a transmit power of each assigned timeslot for uplink
transmission in addition to information about timeslot assignment. In the mobile

station, a transmit power Pup on each uplink PDCH (Packet Data Channel) can be
obtained from the following equation:
[38] MathBgure 1
[Math.l]

[39] where C0 is a power offset, CCH is a power control parameter, r is a system parameter,
L is a normalized received signal level at the mobile station and PMA* is the maximum
allowed transmit power in a cell. The CCH is the channel specific power control
parameter. The power offset C0 is a constant and may be set to 39 dBm for GSM 900
and 36 dBm for DCS 1800 and PCS 1900. The system parameter r is broadcasted on a
packet broadcast control channel (PBCCH) or optionally sent to a mobile station in an
RLC control message.
[40] If the power control parameter CCH is decided when the system parameter r and the
power offset C0 are known, the mobile station can calculate the transmit power Pup with
respect to the corresponding timeslot.
[41] The packet uplink assignment message can include a power control parameter of a
timeslot in addition to information about at least one timeslot, which is necessary by
the mobile station for uplink transmission. In this case, a transmit power can be found
by employing the power control parameter included in the packet uplink assignment
message. The problem is that the power control parameter with respect to each timeslot
cannot be defined when the power control parameter is not included in the packet
uplink assignment message. A method of defining the power control parameter is
needed in order to efficiently control a transmit power. A variety of methods can be
used to define the power control parameter.
[42] fn an embodiment, if a timeslot is assigned through the packet uplink assignment
message, a mobile station can set a power control parameter of the assigned timeslot to
a default value. For example, the default value may be zero. By setting the power
control parameter to the default value, when the packet uplink assignment message is
received, the mobile station can calculate a transmit power with respect to the assigned
timeslot and perform uplink transmission by employing the calculated transmit power.
[43] In another embodiment, a mobile station can calculate a transmit power by
employing a previous power control parameter. The previous power control parameter
refers to a power control parameter that is already used in a packet transfer mode
anterior to a current packet transfer mode. That is, in the case where the mode changes
from a packet transfer mode to a packet idle mode and then becomes a current packet
transfer mode again, a power control parameter that had been used in a previous packet
transfer mode is a previous power control parameter. If a corresponding timeslot has a

previous power control parameter, the mobile station calculates an output power based
on the previous power control parameter. If the mobile station accesses the network for
the first time after power is on or is assigned a timeslot for the first time, a previous
power control parameter does not exist. If a previous power control parameter does not
exist, the mobile station can calculate a transmit power by defining a power control
parameter as a default value.
[44] If a power control parameter is not included in the packet uplink assignment
message, the mobile station can find a transmit power by using a previous power
control parameter or a default value as the power control parameter. Hence, a user
equipment can set a power control parameter automatically without the need to
transmit the power control parameter to each user equipment whenever the network
assigns a new timeslot. Thus, scheduling is simplified and the efficient power control
in a cell is achieved.
[45] FIG. 4 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with another embodiment of the present invention.
[46] Referring to FIG. 4, a mobile station sends a packet channel request message to a
network for radio access (S210). The network sends a multiple TBF uplink assignment
message to the mobile station in response to the packet channel request message
(S220). The multiple TBF uplink assignment message may be transmitted on PACCH.
Unlike the packet uplink assignment message, the multiple TBF uplink assignment
message assigns a multiple TBF to the mobile station. The multiple TBF uplink as-
signment message includes timeslot assignment information for uplink transmission in
each TBF.
47] If the power control parameter is not directly given through the multiple TBF uplink
assignment message, a variety of methods can be used in order to find the transmit
power.
48] In an embodiment, if a timeslot is assigned through the multiple TBF uplink as-
signment message, the mobile station can set a power control parameter of the assigned
timeslot to a default value. For example, the default value may be zero. By setting the
power control parameter to the default value, when the packet uplink assignment
message is received, the mobile station can calculate a transmit power of an assigned
timeslot and perform uplink transmission by employing the calculated transmit power.
49] In another embodiment, the mobile station can calculate a transmit power by
employing a previous power control parameter. The previous power control parameter
refers to a power control parameter that had been used in a packet transfer mode
anterior to a current packet transfer mode. If there exists a previous power control
parameter with respect to a corresponding timeslot, the mobile station calculates an
output power by employing the previous power control parameter. If there does not

exist a previous power control parameter, the mobile station can calculate a transmit
power by setting the power control parameter to a default value.
[50] . FIG. 5 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[51] Referring to FIG. 5, in a packet transfer mode, a mobile station transmits packet data
through an assigned timeslot (S310). During the packet transfer mode, the network can
update power and/or TA (Timing Advance) of the mobile station by sending a packet
power control/TA message to the mobile station (S320). TA can be a value used to
advance a transmit timing to the base station in order to compensate for propagation
delay in the mobile station. The packet power control/TA message can be transmitted
on the PACCH.
[52] Only TA can be updated through the packet power control/TA message. In other
words, this corresponds to a case where the network sends only T A. If TA is updated,
the transmit power of each timeslot can be found by employing a previous power
control parameter. The previous power control parameter is a power control parameter
that had been used by a corresponding timeslot in a current packet transfer mode. That
is, since a current mode is a packet transfer mode, a transmit power parameter that had
been used previously exists in each timeslot in order to transmit old packet data. The
transmit power of the timeslot is found by employing the transmit power parameter
that had been used. If a previous transmit power parameter does not exist, the power
control parameter can be set to a default value.
[53] Only power can be updated through the packet power control/TA message. This cor-
responds to a case where the network sends a power control parameter. Here, a
transmit power is calculated by employing a received power control parameter.
[54] Power with respect to only a part of timeslots can be updated through the packet
power control/TA message. A transmit power with respect to some of the timeslots to
which a transmit power parameter is given is calculated by employing the given
transmit power parameter. A transmit power with respect to the remaining timeslots to
which a transmit power parameter is not given is calculated by employing a previous
power control parameter.
[55] Both power and TA can be updated through the packet power control/TA message.
Even in this case, a transmit power of a timeslot to which a power control parameter is
not given is calculated by employing a previous power control parameter.
[56] The mobile station transmits packet data by employing the obtained transmit power
and the updated power and/or TA (S330).
[57] FIG. 6 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[58] Referring to FIG. 6, in a packet transfer mode, a mobile station transmits packet data

through an assigned times lot (S410). During the packet transfer mode, a network can
update power and/or TA of the mobile station by sending a packet uplink ACK
(Acknowledgment)/NACK (Non-Acknowledgment) message to the mobile station
(S420). The packet uplink ACK/NACK message is a message that is sent from the
network to the mobile station in order to inform the state of a received RLC (Radio
Link Control) data block and can be transmitted on PACCH. The packet uplink ACK/
NACK message includes power and/or TA and can update power and/or TA.
[59] Only power can be updated through the packet uplink ACK/NACK message. That is,
this corresponds to a case where the network sends a power control parameter. Here, a
transmit power is calculated by employing a received power control parameter.
[60] Power with respect to only a part of timeslots can be updated through the packet
uplink ACK/NACK message. A transmit power with respect to some of timeslots to
which a transmit power parameter is given is calculated by employing the given
transmit power parameter. A transmit power with respect to the remaining timeslots to
which a transmit power parameter is not given is calculated by employing a previous
power control parameter.
[61] Both power and TA can be updated through the packet uplink ACK/NACK message.
Even in this case, a transmit power with respect to a timeslot to which a power control
parameter is not given is calculated by employing a previous power control parameter.
[62] The mobile station transmits packet data by employing the obtained transmit power
and the updated power and/or TA (S430).
[63] FIG. 7 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[64] Referring to FIG. 7, in a packet transfer mode, a mobile station transmits packet data
through an assigned timeslot (S510). During the packet transfer mode, the network can
assign an uplink timeslot to the mobile station by sending a packet timeslot reconfigure
message to the mobile station (S520). The packet timeslot reconfigure message can be
transmitted on PACCH.
[65] The packet timeslot reconfigure message can include a power control parameter with
respect to a timeslot in addition to information about at least one timeslot, which is
required by the mobile station for uplink transmission. In this case, a transmit power
can be found by employing the power control parameter included in the packet uplink
assignment message. When the power control parameter is not included in the packet
timeslot reconfigure message, a variety of methods can be used in order to define the
power control parameter with respect to the timeslot.
[66] In an embodiment, if a timeslot is assigned through the packet timeslot reconfigure
message, the mobile station can set a power control parameter, with respect to the
assigned timeslot, to a previously set value. For example, the set value may be zero. By

setting the power control parameter to the previously set value, the mobile station can
calculate a transmit power of the assigned timeslot if the packet timeslot reconfigure
message is received and perform uplink transmission based on the calculated transmit
power.
[67] In another embodiment, the mobile station can calculate a transmit power of an
assigned timeslot by employing a previous power control parameter. The previous
power control parameter can include two kinds. The first previous power control
parameter is a power control parameter that had been used in a corresponding timeslot
in a current packet transfer mode. That is, if an assigned timeslot has once been used in
a current packet transfer mode, a transmit power parameter that has been used becomes
a first previous power control parameter. The second previous power control parameter
is a power control parameter that had been used in a packet transfer mode anterior to a
current packet transfer mode. That is, in the case where the mode changes from a
packet transfer mode to a packet idle mode and then becomes a current packet transfer
mode again, a power control parameter that had been used in a previous packet transfer
mode is a second previous power control parameter. The mobile station gives a priority
to the first previous power control parameter. If the first previous power control
parameter exists, the mobile station can find a transmit power by employing the first
previous power control parameter. If the first previous power control parameter does
not exist and the second previous power control parameter exists, the mobile station
can find a transmit power by employing the second previous power control parameter.
If both the first previous power control parameter and the second previous power
control parameter do not exist, the mobile station can find a transmit power by
employing a default value. As another example, the mobile station can find a transmit
power by employing only one of the first previous power control parameter or the
second previous power control parameter.
[68] The mobile station transmits packet data by employing the obtained transmit power
and the assigned timeslot (S530).
[69] FIG. 8 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention.
[70] Referring to FIG. 8, a mobile station transmits packet data to a network through an
assigned timeslot (S610). During the packet transfer mode, the network can assign an
uplink timeslot to the mobile station by sending a packet uplink assignment message to
the mobile station (S620). In other words, unlike the embodiment of FIG. 3, the packet
uplink assignment message can be sent from the network to the mobile station during
transmission of packet data not a response to a packet channel request message in order
to assign a new timeslot. A default value can be used as a transmit power parameter
with respect to an assigned timeslot.

[71 ] The mobile station transmits packet data by employing the obtained transmit power
and the assigned timeslot (S630).
[72] FIG. 9 is a flowchart illustrating a method of controlling a transmit power in ac-
cordance with still another embodiment of the present invention. This shows a method
of controlling a transmit power during handover.
[73] Referring to FIG. 9, the network transmits a handover command message to the
mobile station on the PACCH (S710). The handover command message is a message
to instruct that the mobile station should leave a current cell and arrive in a new cell.
The handover command message includes information about radio resources, allocated
for a packet-switched service in a new cell, and also includes at least one timeslot as-
signment information.
[74] If a power control parameter with respect to an assigned timeslot is not given, the
mobile station that has received the handover command message determines a power
control parameter as a set value. The mobile station finds a transmit power by
employing the set power control parameter.
[75] The mobile station transmits a handover access message to the network (S720). The
handover access message is to make the network aware that the mobile station has left
the old cell and arrived in the new cell. The handover access message is sent on the
PACCH associated with an uplink TBF allocated in the handover command message.
[76] If a cell is changed, a power control parameter has to be changed. The power control
parameter is sensitive to path loss. Path loss is greatly influenced by a distance
between a mobile station and a network. Thus, if only a timeslot is assigned through a
handover command message during handover, but the power control parameter for the
timeslot is not given, a transmit power can be controlled stably by setting the power
control parameter to a set value.
[77] When a mobile station is assigned a timeslot or updates power and/or timing advance
for uplink transmission, the mobile station can stably control a transmit power of a
timeslot.
[78] The functions described in connection with the embodiments disclosed herein may
be performed by implemented by hardware, software or a combination thereof. The
hardware may be implemented by a microprocessor, a controller, an application
specific integrated circuit (ASIC) and a processor. Design, development and imple-
mentation of the software are well known to those skilled in the art based on the
detailed description.
[79] As the present invention may be embodied in several forms without departing from
the spirit or essential characteristics thereof, it should also be understood that the
above-described embodiments are not limited by any of the details of the foregoing de-
scription, unless otherwise specified, but rather should be construed broadly within its

spirit and scope as defined in the appended claims. Therefore, all changes and modi-
fications that fall within the metes and bounds of the claims, or equivalence of such
metes and bounds are intended to be embraced by the appended claims.

Claims
[1] A method of controlling a transmit power at a mobile station in a wireless com-
munication system, the method comprising:
determining a power control parameter of an assigned timeslot, wherein the
value of the power control parameter is a default value if the assigned timeslot is
assigned with no power control parameter and the value of the power control
parameter is the current value if the assigned timeslot is already used by the
mobile station; and
determining the transmit power Pup on an uplink channel from the following
equation:

where Co is a power offset, QH is the power control parameter, r is a system
parameter, L is a normalized received signal level at die mobile station and PMAX
is the maximum allowed transmit power in a cell.
[2] The method of claim 1, further comprising transmitting data on the uplink
channel using the transmit power.
[3] The method of claim 1, wherein the uplink channel is a packet data channel
(PDCH).
[4] The method of claim 1, wherein the system parameter is broadcasted on a packet
broadcast control channel (PBCCH).
[5] The method of claim 1, further comprising:
receiving a downlink control message for allocating at least one timeslot, the
control message allocating the assigned timeslot without any power control
parameter for the assigned timeslot.
[6] The method of claim 5, wherein the downlink control message is a packet uplink
assignment message to assign uplink resources.
[7] The method of claim 5, wherein the downlink control message is a multiple
temporary block flow (TBF) uplink assignment message to assign uplink
resources.
[8] The method of claim 5, wherein the downlink control message is a packet
timeslot reconfigure message to assign uplink resources.
[9] The method of claim 5, wherein the downlink control message is a handover
command message from a network to command the mobile station to leave a
current cell and change to a new cell.
[ 10] The method of claim 1, further comprising:
receiving a downlink control message for updating a timing advance.

[11] 11. The method of claim 1, further comprising:
receiving a downlink control message for updating a timing advance and in-
dicating the status of a received radio link control (RLC) data blocks.
[12] The method of claim 1, wherein the default value is zero.
[13] A method of controlling a transmit power at a mobile station during handover in
a wireless communication system, the method comprising:
receiving a handover command message from a network to command the mobile
station to leave a current cell and change to a new cell, the handover command
message comprising radio resources assigned for packet-switched (PS) services
in the new cell, the radio resources comprising information on at least one
assigned timeslot;
determining a power control parameter of an assigned timeslot as a default value
if the assigned timeslot is assigned with no power control parameter; and
determining the transmit power Pup on an uplink channel from the following
equation:

where Co is a power offset, CCH is the power control parameter, r is a system
parameter, L is a normalized received signal level at the mobile station and PMAX
is the maximum allowed transmit power in a cell.
[14] 14. The method of claim 13, further comprising:
transmitting a handover access message to the network to make the network
aware that the mobile station has left the old cell and arrived in the new cell.
[15] The method of claim 13, wherein the default value is zero.
[16] The method of claim 13, wherein the handover command message is received on
a packet associated control channel (PACCH).
[17] 17. A mobile station comprising:
a RF (Radio Frequency) unit for transmitting radio signals using a transmit
power;
a memory configured to store a default value for a power control parameter; and
a processor coupled to the RF unit and the memory, and configured to determine
a power control parameter of an assigned timeslot, wherein the value of the
power control parameter is the default value if the assigned timeslot is assigned
with no power control parameter and the value of the power control parameter is
the current value if the assigned timeslot is already used by the mobile station;
and
determine the transmit power Pup from the following equation:


where C0 is a power offset, CCH is the power control parameter, r is a system
parameter, L is a normalized received signal level at the mobile station and PMAX
is the maximum allowed transmit power in a cell.
[18] The mobile station of claim 17, wherein the transmit power is determined during
handover.
[ 19] The mobile station of claim 17, wherein the assigned timeslot is a part of a time
division multiple access (TDMA) frame composed of eight timeslots.

A method of controlling a transmit power includes determining a power control parameter of an assigned timeslot, wherein the value of the power control parameter is a default value if
the assigned timeslot is assigned with no power control parameter and the valae of the power control parameter is the current value if the assigned timeslot is already used by the mobile station and determining the transmit power on an uplink channel.

Documents:

2154-KOLNP-2009-(15-07-2014)-ANNEXURE TO FORM 3.pdf

2154-KOLNP-2009-(15-07-2014)-CORRESPONDENCE.pdf

2154-KOLNP-2009-(27-05-2014)-CORRESPONDENCE.pdf

2154-KOLNP-2009-(27-05-2014)-OTHERS.pdf

2154-KOLNP-2009-(30-06-2014)-ABSTRACT.pdf

2154-KOLNP-2009-(30-06-2014)-ANNEXURE TO FORM 3.pdf

2154-KOLNP-2009-(30-06-2014)-CLAIMS.pdf

2154-KOLNP-2009-(30-06-2014)-CORRESPONDENCE.pdf

2154-KOLNP-2009-(30-06-2014)-DESCRIPTION (COMPLETE).pdf

2154-KOLNP-2009-(30-06-2014)-DRAWINGS.pdf

2154-KOLNP-2009-(30-06-2014)-FORM-2.pdf

2154-KOLNP-2009-(30-06-2014)-PA.pdf

2154-KOLNP-2009-(30-06-2014)-PETITION UNDER RULE 137.pdf

2154-kolnp-2009-abstract.pdf

2154-KOLNP-2009-ASSIGNMENT.pdf

2154-kolnp-2009-claims.pdf

2154-kolnp-2009-correspondence.pdf

2154-kolnp-2009-description (complete).pdf

2154-kolnp-2009-drawings.pdf

2154-kolnp-2009-form 1.pdf

2154-kolnp-2009-form 18.pdf

2154-kolnp-2009-form 3.pdf

2154-kolnp-2009-form 5.pdf

2154-kolnp-2009-gpa.pdf

2154-kolnp-2009-international publication.pdf

2154-kolnp-2009-pct priority document notification.pdf

2154-kolnp-2009-pct request form.pdf

2154-kolnp-2009-specification.pdf

abstract-2154-kolnp-2009.jpg


Patent Number 265249
Indian Patent Application Number 2154/KOLNP/2009
PG Journal Number 08/2015
Publication Date 20-Feb-2015
Grant Date 16-Feb-2015
Date of Filing 08-Jun-2009
Name of Patentee LG ELECTRONICS INC.
Applicant Address 20, YEOUIDO-DONG, YEONGDEUNGPO-GU, SEOUL 150-721
Inventors:
# Inventor's Name Inventor's Address
1 KOO, HYOUN HEE LG R & D COMPLEX, 533, HOGYE 1-DONG, DONGAN-GU, ANYANG-SI, GYEONGKI-DO 431-749
PCT International Classification Number H04B 7/26
PCT International Application Number PCT/KR2008/001505
PCT International Filing date 2008-03-18
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10-2007-0027159 2007-03-20 Republic of Korea