NZ701508B2 - Radio network node, user equipment and methods therein - Google Patents
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- NZ701508B2 NZ701508B2 NZ701508A NZ70150812A NZ701508B2 NZ 701508 B2 NZ701508 B2 NZ 701508B2 NZ 701508 A NZ701508 A NZ 701508A NZ 70150812 A NZ70150812 A NZ 70150812A NZ 701508 B2 NZ701508 B2 NZ 701508B2
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- user equipment
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- power control
- power
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- 238000006731 degradation reaction Methods 0.000 abstract description 3
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Abstract
The present disclosure relates to minimising or reducing the degradation of the performance in a radio communications network. For example, minimising or reducing interference between uplink and downlink transmissions. There is disclosed a method in a user equipment (10) for determining a transmit power to be used by the user equipment (10) when transmitting in a radio communications network, the user equipment (10) being served by a radio network node (12, 12’) in the radio communications network. The method comprises receiving multiple sets of power control parameters from the radio network node (12, 12’) during configuration of the user equipment (10). The multiple sets of power control parameters are stored at the user equipment (10), and comprise a specific set of power control parameters to apply for one or more subframes. The method further comprises receiving, from the radio network node (12, 12’), an indication indicating the set of power control parameters out of the multiple sets of power control parameters. The indication indicates a subframe comprised in the one or more subframes. The method further comprises determining the transmit power for the indicated subframe based on the indicated set of power control parameters. ower to be used by the user equipment (10) when transmitting in a radio communications network, the user equipment (10) being served by a radio network node (12, 12’) in the radio communications network. The method comprises receiving multiple sets of power control parameters from the radio network node (12, 12’) during configuration of the user equipment (10). The multiple sets of power control parameters are stored at the user equipment (10), and comprise a specific set of power control parameters to apply for one or more subframes. The method further comprises receiving, from the radio network node (12, 12’), an indication indicating the set of power control parameters out of the multiple sets of power control parameters. The indication indicates a subframe comprised in the one or more subframes. The method further comprises determining the transmit power for the indicated subframe based on the indicated set of power control parameters.
Description
RADIO NETWORK NODE, USER EQUIPMENT AND METHODS THEREIN
TECHNICAL FIELD
The embodiments herein relate to a radio network node, a user equipment and
methods therein. In particular, embodiments herein relate to determine and to control
transmit power to be used by the user equipment when transmitting in a radio
communications network.
BACKGROUND
In today’s radio communications networks a number of different technologies are
used, such as Long Term Evolution (LTE), LTE-Advanced, Wideband Code Division
Multiple Access (WCDMA), Global System for Mobile communications/Enhanced Data
rate for GSM Evolution (GSM/EDGE), Worldwide Interoperability for Microwave Access
(WiMax), or Ultra Mobile Broadband (UMB), just to mention a few possible
implementations. A radio communications network comprises radio base stations
providing radio coverage over at least one respective geographical area, the
geographical area may be called a cell. The cell definition may also incorporate
frequency bands used for transmissions, which means that two different cells may cover
the same geographical area but using different frequency bands. User equipments (UE)
are served by the respective radio base station and are communicating with respective
radio base station. The user equipments transmit data over an air or radio interface to
the radio base stations in uplink (UL) transmissions and the radio base stations transmit
data over an air or radio interface to the user equipments in downlink (DL)
transmissions.
In e.g. the LTE uplink user equipment transmit power control is applied in order
to lower interference and reduce user equipment battery consumption. The power
control formula for transmit or transmission power for uplink shared channel, P (i)
PUSCH,c
is described in Third Generation Partnership Project (3GPP) TS 36.213 Physical Layer
procedures, v 10.4.0 section 5.1.1 where
P (i),
CMAX,c
P (i)=min
PUSCH,c
10log (M (i))+P (j)+a (j) PL +D (i)+ f (i)
PUSCH,c O_PUSCH,c c c TF,c c
[dBm]
6788864_4.doc
where,
P (i)
is the configured user equipment maximum transmit power,
CMAX,c
M (i)
is the bandwidth of the Physical Uplink Shared Channel (PUSCH) resource
PUSCH,c
assignment expressed in number of resource blocks, this term compensates for varying
assigned bandwidth,
P (j) is a configurable power target, this parameter depends on j where j is set
O_PUSCH,c
dependent on if the transmission relates to a normal transmission, a Semi Persistent
Scheduling (SPS) transmission or an Random Access Response message,
a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1}
is a 3-bit parameter and relates to path-loss
compensation, i.e. how much the user equipment should compensate its transmit power
dependent on increasing/decreasing path-loss towards the radio base station,
PL is the downlink path loss estimate,
BPRE K PUSCH
D (i)=10log ((2 -1)b ) is an offset dependent on if the
TF,c 10 offset
transmission is a transmission only containing uplink control information or not,
f (i)
is a dynamic part controlled by power control commands sent in the grant on the
downlink control channel. It can either be absolute commands or accumulative
commands.
The user equipment transmit power is hence controlled by the radio
communications network, e.g. a radio base station, with one slow component,
configuring P (j) and , and one fast component in the power control
O_PUSCH,c
f (i)
commands . The different components may be used to provide a good received
signal to interference and noise ratio (SINR) while keeping the interference to
neighbouring cells low.
In 3GPP the potential introduction of more flexible Time Division Duplex (TDD)
configurations has been assessed. In TDD the same frequency resources are used both
for uplink and downlink transmissions where resources are divided between the links in
time. The division is in LTE controlled by the eNodeB, i.e. the radio base station, which
signals an uplink/downlink pattern to the user equipment, where the current standard
supports configurations with from around 10% up to around 60% uplink. So far, the
6788864_4.doc
configuration is performed using system broadcast and is hence changed relatively
slowly. If neighbouring cells use different TDD configurations so called eNodeB-to-
eNodeB interference may occur in addition to UE-to-UE interference. eNodeB-to-
eNodeB interference is the downlink transmission in one cell that will be seen as
interference for a simultaneous uplink transmission, on the same frequency, in a
different cell. This interference may in some deployments be many multitudes stronger
than typical uplink interference stemming from other transmitting user equipments due
to higher output power from a radio base station compared to a user equipment and
also because of possibly different propagation conditions between radio base stations
as compared to between user equipments and radio base stations. Put another way,
during a 10ms radioframe, for a given radio base station serving the user equipment, the
UL subframes in which eNodeB-to-eNodeB interference occurs, due to the fact that
another radio base station is using the same subframes for DL transmission, experience
a higher level of interference and noise as compared to UL subframes for which there
are no eNodeB-to-eNodeB interference since all radio base stations are using these
subframes for UL transmissions.
In TDD systems the same frequency is used for both uplink and downlink
transmissions. To protect the system from interference between uplink and downlink a
guard period is inserted between uplink and downlink periods. This guard period when
switching from downlink to uplink is set such that the user equipments will have time to
switch from receiving to transmitting but also to be longer than the propagation delay
from radio base station received with significant interfering power. In some special
conditions the propagation properties may change such that transmissions of radio base
stations from further away may be received with high power. In these cases the guard
period may not have been set to a large enough value and high interference may then
be experienced in the first uplink subframe, which first uplink subframe being the first in
time UL subframe after a downlink/switching subframe.
There is also a possibility that there are multiple TDD carriers on adjacent
frequencies in the same frequency band. For example, in the 2300-2400MHz band,
there may be multiple carriers, each using e.g. a 20MHz bandwidth. Due to imperfect
filtering, the different carriers cause interference to each other. For example, the
downlink transmission on one carrier causes interference to the uplink reception on
another carrier. At the radio base station receiver side, interference levels may then be
higher during the subframes, where downlink transmission occurs on the adjacent
6788864_4.doc
carriers, as compared to the subframes, where also the adjacent carriers are used for
uplink.
The UL/DL interference may also occur in case of Global Positioning System
(GPS) sync failure in any neighbouring TDD cells. In this case, the unsynchronized radio
base station may interfere with the other radio base station(s) and similar situations may
occur.
There are possibilities also that Band 7, i.e. DL frequency band at 2620-
2670MHz and UL 2500-2570MHz, Frequency Division Duplex (FDD) systems and band
38, i.e. frequency band of 2570-2620MHz, TDD systems may experience similar
problems due to adjacent channel interference. Hence, even for an FDD carrier,
interference may be relatively high in certain subframes, where downlink transmissions
occur on an adjacent carrier, as compared to other subframes, where no downlink but
user equipment uplink transmissions occurs.
Currently, the radio base station configures the user equipment with power
control parameters for the user equipment to use when determining, at the user
equipment, transmit power for transmissions to the radio base station. The radio base
f (i)
station may then use e.g. the power command to tune the transmit power of the
user equipment. The power control parameters may be periodically updated and the
f (i)
power command changes the transmit power in a rather slow manner. The types
of interferences mentioned above introduce a rather drastic interference increase in
some subframes, reducing the performance of the radio communications network.
SUMMARY
The present invention provides a method in a user equipment for determining a
transmit power to be used by the user equipment when transmitting in a radio
communications network, wherein the user equipment is served by a radio network
node in the radio communications network, the method comprising: receiving multiple
sets of power control parameters from the radio network node during configuration of
the user equipment, wherein the multiple sets of power control parameters are stored at
the user equipment, wherein the multiple sets of power control parameters comprise a
specific set of power control parameters to apply for one or more subframes; receiving,
from the radio network node, an indication indicating the set of power control
parameters out of the multiple sets of power control parameters, wherein the indication
indicates a subframe comprised in the one or more subframes; determining the transmit
6788864_4.doc
power for the indicated subframe based on the indicated set of power control
parameters.
The present invention further provides a method in a radio network node for
controlling a transmit power of a user equipment in a radio communications network,
wherein the radio network node serves the user equipment in the radio communications
network, the method comprising: configuring the user equipment with multiple sets of
power control parameters by sending the multiple sets to the user equipment, wherein
the multiple sets of power control parameters comprise a specific set of power control
parameters to apply for one or more subframes; and transmitting an indication to the
user equipment, wherein the indication indicates the set of power control parameters out
of the multiple sets of power control parameters stored at the user equipment, thereby
controlling the transmit power of the user equipment, wherein the indication indicates a
subframe comprised in the one or more subframes.
The present invention further provides a user equipment for determining a
transmit power to be used by the user equipment when transmitting in a radio
communications network, wherein the user equipment is configured to be served by a
radio network node in the radio communications network, the user equipment
comprising: a receiver configured to receive multiple sets of power control parameters
from the radio network node during configuration of the user equipment, and to receive
an indication from the radio network node, wherein the multiple sets of power control
parameters comprise a specific set of power control parameters to apply for one or more
subframes, wherein the indication indicates the set of power control parameters out of
the multiple sets of power control parameters, and wherein the indication indicates a
subframe comprised in the one or more subframes; a memory configured to have the
multiple sets of power control parameters stored thereon; and a determining circuit
configured to determine a transmit power for the indicated subframe based on the
indicated set of power control parameters.
The present invention still further provides a radio network node for controlling a
transmit power of a user equipment in a radio communications network, wherein the
radio network node is configured to serve the user equipment in the radio
communications network, the radio network node comprising: a transmitter configured to
transmit an indication to the user equipment; a configuring circuit configured to configure
the user equipment with multiple sets of power control parameters by sending the
multiple sets to the user equipment over the transmitter, wherein the multiple sets of
power control parameters comprise a specific set of power control parameters to apply
6788864_4.doc
for one or more subframes; wherein the indication indicates the set of power control
parameters out of the multiple sets of power control parameters stored at the user
equipment, thereby controlling the transmit power of the user equipment , wherein the
indication indicates a subframe comprised in the one or more subframes.
An object of embodiments herein is to minimize degradation of the performance
in a radio communications network.
According to an aspect the object may be achieved by a method in a user
equipment for determining a transmit power to be used by the user equipment when
transmitting in a radio communications network. The user equipment is served by a
radio network node in the radio communications network. The user equipment receives,
from the radio network node, an indication indicating a set of power control parameters
out of multiple sets of power control parameters. The multiple sets of power control
parameters are stored at the user equipment. The user equipment then determines a
transmit power based on the indicated set of power control parameters.
As the user equipment determines the transmit power based on the indication,
the transmit power is controlled by the radio network node in a flexible and efficient
manner. Thus, the degradation of the performance is reduced as the user equipment
may perform drastic transmit power changes due to the feature of using the indication to
determine the set of control parameters.
According to another aspect the object may be achieved by a method in the
radio network node for controlling the transmit power of the user equipment in the radio
communications network. As stated above, the radio network node serves the user
equipment in the radio communications network. The radio network node determines
the set of power control parameters to be used by the user equipment for determining
transmit power of the user equipment. The radio network node further transmits the
indication to the user equipment. The indication indicates the set of power control
parameters out of multiple sets of power control parameters stored at the user
equipment. The transmit power of the user equipment is thereby controlled.
According to yet another aspect the object may be achieved by a user
equipment for determining a transmit power to be used by the user equipment when
transmitting in the radio communications network. The user equipment is configured to
be served by a radio network node in the radio communications network. The user
equipment comprises a memory configured to have the multiple sets of power control
parameters stored thereon. The user equipment further comprises a receiver configured
to receive, from the radio network node, an indication indicating a set of power control
6788864_4.doc
parameters out of the stored multiple sets of power control parameters. Furthermore,
the user equipment comprises a determining circuit configured to determine a transmit
power based on the indicated set of power control parameters.
According to still another aspect the object may be achieved by a radio network
node for controlling the transmit power of the user equipment in the radio
communications network. The radio network node is configured to serve the user
equipment in the radio communications network. The radio network node comprises a
determining circuit configured to determine the set of power control parameters to be
used by the user equipment for determining transmit power of the user equipment. The
radio network node further comprises a transmitter configured to transmit the indication
to the user equipment. The indication indicates the set of power control parameters out
of multiple sets of power control parameters stored at the user equipment. The transmit
power of the user equipment is thereby controlled by the radio network node.
Embodiments herein increase flexibility in transmit power setting by indicating
the set of power control parameters to determine transmit power out of multiple sets of
power control parameters. Thereby may the set of power control parameter be quickly
changed and thus the transmit power enabling transmissions also in subframes with
high interference levels or improved performance in subframes with less sensitivity to
e.g. interference in neighbour cells.
BRIEF DESCRIPTION OF THE DRAWINGS
Embodiments will now be described in more detail in relation to the enclosed
drawings, in which:
Fig. 1 is a schematic overview depicting a radio communications network according to
embodiments herein,
Fig. 2 is a schematic combined flowchart and signalling scheme according to some
embodiments herein,
Fig. 3 is a schematic combined flowchart and signalling scheme according to some
embodiments herein,
Fig. 4 is a flowchart depicting a method in a user equipment according to embodiments
herein,
Fig. 5 is a block diagram depicting a user equipment according to embodiments herein,
Fig. 6 is a flowchart depicting a method in a radio network node according to
embodiments herein, and
Fig. 7 is a block diagram depicting a radio network node according to embodiments
herein.
6788864_4.doc
DETAILED DESCRIPTION
is a schematic overview depicting a radio communications network
according to embodiments herein. The radio communications networks may use a
number of different technologies, such as LTE, LTE-Advanced, WCDMA, GSM/EDGE,
WiMax, or UMB or similar.
The radio communications network comprises a radio network node 12,
exemplified herein as a radio base station 12’, providing radio coverage over at least
one geographical area, which geographical area may be referred to as a cell 11. The
cell definition may also incorporate frequency bands used for transmissions. The radio
base station 12’ may also be referred to as e.g. a NodeB, an evolved Node B (eNB,
eNode B), a base transceiver station, Access Point Base Station, base station router, or
any other network unit capable to communicate with the user equipment 10 served by
the radio base station 12’ depending e.g. of the radio access technology and
terminology used. The radio network node 12 will herein be exemplified as the radio
base station 12’ but may further comprise a relay node, a beacon node or similar.
A user equipment (UE) 10 is communicating with the radio base station 12’.
The user equipment 10 transmits data over an air or radio interface to the radio base
station 12’ in uplink (UL) transmissions and the radio base station 12’ transmits data
over an air or radio interface to the user equipment 10 in downlink (DL) transmissions. It
should be understood by the skilled in the art that “user equipment” is a non-limiting
term which means any wireless terminal, device or node e.g. Personal Digital Assistant
(PDA), laptop, mobile, sensor, relay, mobile tablets or even a small base station
communicating within respective cell.
In prior art good transmit power control is supported in situations where the
required transmit power per resource block varies slowly with power control commands
f (i)
, for example up to 4dB, between subframes used for transmission but it is not
suited to handle large variations due to fast variation in interference levels or knowledge
of how much harm the interference will cause in other cells. Specifically, in case some
subframes suffer from e.g. severe eNodeB-eNodeB interference, whereas other
subframes do not, a power control process, as described herein, which does take this
into account will enhance the performance of the radio communications network. A
particular case of interference variations are interference variations that are periodic with
the duration of a radio frame. An example of this comprises the case where the first
6788864_4.doc
uplink subframe after the guard period at the switch from downlink to uplink always
suffers from higher interference due to interference from a remote radio base station.
Embodiments herein increase the power control flexibility in order to handle large
variations in wanted transmit power or transmission power. The radio base station 12’
transmits an indication to the user equipment 10. The indication indicates a set of power
control parameters out of multiple sets of power control parameters. The multiple sets of
power control parameters are stored at the user equipment 10, e.g. in an internal or
external memory, and the set of power control parameter is to be used by the user
equipment 10 when determining transmit power at the user equipment 10. Thus, a
rather large change in transmit power in some subframes may be signalled with just an
indication.
The indication may be an explicit indication, such as an index of an indexed list
of sets of power control parameters to use when transmitting in a scheduled subframe.
Alternatively, the indication may be an implicit indication, such as an indication of a
subframe to use; wherein the user equipment 10 is configured to use different power
control parameters to determine transmit power for different subframes.
The set of power control parameters may comprise any one or any combinations
P (i)
- configured maximum transmit power ;
CMAX,c
- a target received power P (j) , this parameter depends on j where j is
O_PUSCH,c
set dependent on if the transmission relates to a normal transmission, an SPS
transmission or an Random Access Response message;
a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1}
- a 3-bit parameter, , which relates to
path-loss compensation, i.e. how much the user equipment should compensate
its power dependent on increasing/decreasing path-loss towards the radio base
station;
- a power offset D (i) dependent on if the transmission is a transmission only
TF,c
containing uplink control information or not,
BPRE K PUSCH
D (i)=10log ((2 -1)b ); and
TF,c 10 offset
f (i)
- a dynamic part controlled by power control commands , which may be
sent in the grant on the downlink control channel. It can either be absolute
commands or accumulative; just to mentions a few examples.
6788864_4.doc
Thus, embodiments herein increase the power control flexibility in order to
handle large variations in wanted transmit power. Some embodiments herein achieve
the power control flexibility by a signaling method enabling the user equipment 10 to
switch between multiple preconfigured power control parameters and the user
equipment 10 may in some embodiments also switch between accumulated power
control commands. In some embodiments, the flexibility is achieved by applying different
power control parameters when determining transmit power, which power control
parameters are dependent on subframe indices according to a preconfigured pattern.
For example, the radio base station sends a grant for a first subframe, e.g. subframe
index 4, and the user equipment 10 retrieves the set of power control parameters for
that first subframe stored at the user equipment 10. A different set of power control
parameters for other subframes, e.g. subframe indices 0-3 and 5-9, are also already
stored at the user equipment 10 during configuration.
Fig. 2 is a schematic combined flowchart and signalling scheme according to
some embodiments herein. Fig. 2 illustrates an explicit manner of signalling the set of
power control parameters to use when applying transmit power at the user equipment
for transmission to the radio base station 12’. The illustrated embodiment enables an
efficient signaling to switch between different sets of power control parameters e.g. in a
stored list of different sets of power control parameters.
Action 201. The user equipment 10 is configured by the network, e.g. radio base
station 12’ or other network node, with multiple sets of power control parameters, also
referred to as power control processes. This may be performed via higher layer
signaling such as Radio Resource Control (RRC) signaling or similar. The radio base
station 12’ may e.g. signal or transmit to the user equipment 10 a first set of power
control parameters A and a second set of power control parameters B. The first set of
power control parameters A and the second set of power control parameters B may be
used by the user equipment 10 when determining transmit power for transmissions to
the radio base station 12’.
Action 202. The radio base station 12’ schedules a radio resource such as a
subframe to the user equipment 10 in response to an UL request or similar received
from the user equipment 10.
Action 203. The radio base station 12’ then determines a set of power control
parameters to use for the scheduled subframe. E.g. the radio base station 12’ may
estimate or receive indication of interference in the subframe from a neighbouring cell.
6788864_4.doc
The radio base station 12’ may then determine that it does not matter if the user
equipment 10 transmits with full power in this subframe and selects a set of power
control parameters indicating full transmit power. As a different example, the radio base
station 12’ estimates or detects interference from user equipments between cells and
wants the user equipment 10 to reduce its transmit power. The radio base station 12’
may then determine or select a set with power control parameters indicating a reduced
transmit power. As alternative of additional embodiments, the radio base station 12’ may
determine that a load in the cell 11 is below a threshold and may determine a set of
power control parameters for the user equipment 10 with no limits of the transmit power
as the load is low, or the opposite.
Action 204. The radio base station 12’ then transmits or signals the scheduled
subframe and an indication to the user equipment 10 in e.g. an uplink grant message for
a transmission using the scheduled subframe. The indication indicates what set of
power control parameters to use when determining transmit power at the user
equipment 10. The indication may be a pointer e.g. an index in an indexed list of sets of
power control parameters. The radio base station 12’ may also signal an absolute or
f (i)
accumulative power control command in the uplink grant message or separate.
Action 205. The user equipment 10 may then retrieve set of the power control
parameters indicated by the received indication from e.g. a stored indexed list.
Action 206. The user equipment 10 then determines transmit power based on
the retrieved set of power control parameters and may also apply the power control
f (i)
command if present.
Action 207. The user equipment 10 may then apply the determined transmit
power for the granted signal transmission of the subframe. Thus, the user equipment 10
transmits e.g. a reference signal or a data transmission, with the determined transmit
power.
For example, the radio base station 12’ may transmit a grant for subframe x and
indicate the second set of power control parameters B. The user equipment 10 may
then use subframe x with a transmit power, which transmit power is based on the
second set of power control parameters B.
As indicated above the transmit power may be determined from the formula
P (i),
CMAX,c
P (i)=min
PUSCH,c
10log (M (i))+P (j)+a (j) PL +D (i)+ f (i)
PUSCH,c O_PUSCH,c c c TF,c c
In case of accumulative power control commands different accumulations are
6788864_4.doc
done for the different processes. For example, with multiple different accumulations
f (i) , f (i) … where all processes are updated for each subframe according to
c,0 c,1
f (i)= f (i-1)"n unless a power control command indicating a selected process, x,
c,n c,n
is updated with the power control command value, f (i)= f (i-1)+r . Only the
c,x c,x
selected process f (i) is then used in the formula.
Fig. 3 is a schematic combined flowchart and signalling scheme according to
some embodiments herein. Fig. 3 illustrates an implicit manner of signalling the set of
power control parameters to use when determining transmit power at the user
equipment 10. In these embodiments the power control parameters to use when
determining transmit power is not signalled in the uplink grant message, instead is the
user equipment 10 preconfigured with one or more subframes, such as a set of
subframe indices, to apply a specific set of power control parameters for.
Action 301. The user equipment 10 may be configured by the network, e.g.
radio base station 12’ or other network node, with multiple sets of power control
parameters, also referred to as power control processes. This may be performed via
higher layer signaling such as Radio Resource Control (RRC) signaling or similar. E.g.
the radio base station 12’ may transmit or signal a first set of power control parameters
S1 to the user equipment 10. This set may be used by default for of all subframes.
However, the radio base station 12’ may further transmit or signal another set of power
control parameters S2 comprising one or more power control parameters, such as e.g.
power offset, which is different than the previously configured set for a bit set S of
subframes. The bit set S comprises bits indicating subframe numbers. The bit set S
indicates for which certain subframes the user equipment 10 should apply the other set
of power control parameters S2 comprising one or more power control parameters when
determining transmit power. The bit set S may comprise one or more subframes. This
configuration may be signaled from the radio base station 12’, for example, using a bit
set indicating for what subframe/s a set of power control parameters is valid.
Action 302. The radio base station 12’ schedules a radio resource such as a
subframe to the user equipment 10 in response to an UL request for resources or
similar. It should be noted here that the scheduling is performed taking into account
which set of power control parameters to use at the user equipment 10. Thus, action
302 corresponds to actions 202 and 203 in Fig. 2. As an example, a certain set of power
control parameters may be used for certain subframes. The certain subframes may be
6788864_4.doc
subframes used in neighbouring cells to the cell 11 for downlink transmissions. Thereby,
an eNodeB-to-eNodeB interference may occur for transmission in these certain
subframes and one may increase performance by e.g. letting the user equipment 10
transmit with no limitations on transmit power in these certain subframes, since these
are subframes already with high possible interferences.
Action 303. The radio base station 12’ then transmits an uplink grant message
indicating the scheduled subframe to the user equipment 10. The radio base station 12’
may e.g. transmit the uplink grant message indicating to use a subframe x. This means
that the set of power control parameters is implicitly indicated as the subframe x has a
preconfigured set of power control parameter/s stored in a memory at the user
equipment 10. The radio base station 12’ may dynamically schedule different subframes
to user equipments in the cell 11.
Action 304. The user equipment 10 retrieves the power control parameter or
parameters, from the set of power control parameters, to be used when determining
transmit power for the scheduled subframe. That is, the set of power control parameters
is the one stored at the user equipment 10 related to the indicated subframe. E.g. if the
subframe is in the bitset S the other set of power control parameters S2, such as a
power offset, is used for that subframe. However, if the subframe is not in the bitset S
the default set of power control parameters S1 is used.
Action 305. The user equipment 10 uses the retrieved power control parameters
when determining transmit power to use e.g. when performing a data transmission using
the scheduled subframe.
Action 306. The user equipment 10 may then transmit a data or reference signal
towards the radio base station 12’ by applying or using the determined transmit power.
Thus, the implicit indication performed in Action 303 may be signaled from the
network, for example, using a bit set indicating for what subframe a set of power control
parameters is valid. For example, the first set of power control parameters is used for
certain uplink subframes and other sets of power control parameters are used for other
subframes, for example, flexible subframes in LTE TDD systems implementing flexible
TDD. The radio base station 12’ may then implicitly signal or indicate what set of control
parameters to apply by selecting a subframe to schedule transmissions from the user
equipment 10 and transmit a grant for that subframe to the user equipment 10. The
power control parameters to apply may e.g. comprise fixed preconfigured power offset,
a whole set of new parameters or a different accumulated power control entity. The
6788864_4.doc
accumulated power control entity may also be same for the different sets of power
control parameters.
As an example, each 1ms subframe of a 10ms radio frame may have its own set
of power control parameters configured by higher layer signalling. More specifically, the
power control parameter target received power, P (j) , is configured separately
O_PUSCH,c
for each UL subframe whereas other power control parameters and variables are
shared between all subframes. Additionally or alternatively, the power control parameter
Maximum (Allowed) Transmit power P (i) may be configured separately for each
CMAX,c
UL subframe, in order to avoid UE-to-UE interference between different cells or systems
thereby reducing the maximum allowed transmit power.
An advantage of embodiments herein is to increase flexibility in uplink transmit
power control enabling uplink transmissions also in subframes with high interference
levels or improved performance in subframes with less sensitivity to interference in
neighbour cells.
The method actions in the user equipment 10 for determining a transmit power to
be used by the user equipment 10 when transmitting in a radio communications
network, according to some general embodiments will now be described with reference
to a flowchart depicted in Fig. 4. The user equipment 10 is served by the radio network
node 12 in the radio communications network. The steps do not have to be taken in the
order stated below, but may be taken in any suitable order. Actions merely performed in
some embodiments are marked as dashed boxes.
Action 401. The user equipment 10 may receive the multiple sets of power
control parameters from the radio network node 12 during configuration of the user
equipment 10.
Action 402. The user equipment 10 may store the received multiple sets of
power control parameters at the user equipment.
Action 403. The user equipment 10 receives, from the radio network node 12,
an indication indicating a set of power control parameters out of multiple sets of power
control parameters. The multiple sets of power control parameters are, as stated above,
stored at the user equipment 10. The multiple sets of power control parameters may
comprise a specific set of power control parameters to apply for one or more subframes,
and wherein the indication indicates a subframe comprised in the one or more
subframes. E.g. the indication may be a subframe with a preconfigured set of power
control parameters being different than a default set of power control parameters. The
6788864_4.doc
set of power control parameters may comprise one or more power control parameters:
such as a maximum transmit power; a target received power; a value indicating
percentage of a pathloss that is to be taken into account when determining transmit
power; a power offset value; and a power command value. Furthermore, the indication
may be comprised in an uplink grant message. The indication may further e.g. be a
pointer in a list of sets of power control parameters, wherein the pointer indicates in the
list what set of power control parameter to apply by the user equipment 10 when
determining the transmit power. E.g. the indication may be an index of an indexed list,
wherein each index represents a set of power control parameters, such as a maximum
transmit power or similar.
Action 404. The user equipment 10 determines the transmit power based on the
indicated set of power control parameters. For example, the user equipment 10
determines transmit power using a formula defined as:
P (i),
CMAX,c
P (i)=min
PUSCH,c
10log (M (i))+P (j)+a (j) PL +D (i)+f (i)
PUSCH,c O_PUSCH, c c c TF,c c
where:
P (i) is the transmit power for subframe i over a physical uplink shared
PUSCH,c
channel;
P (i)
is the maximum transmit power;
CMAX,c
M (i)
is a bandwidth of a Physical Uplink Shared Channel resource
PUSCH,c
assignment expressed in number of resource blocks;
P (j) is the target received power;
O_PUSCH,c
a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1}
, and is the value indicating percentage
of a pathloss that is to be taken into account when determining transmit power;
PL is the downlink path loss estimate;
D (i) is the power offset value; and
TF,c
f (i) is the power command value.
In some embodiments the user equipment 10 receives an accumulative power
command. Then, the user equipment 10 determines to accumulate the accumulative
power command with a previously used power command. The user equipment 10 may
do different accumulations for different sets of power control parameters.
6788864_4.doc
Fig. 5 is a block diagram depicting a user equipment 10 for determining a
transmit power to be used by the user equipment 10 when transmitting in the radio
communications network. The user equipment 10 is configured to be served by the radio
network node 12 in the radio communications network.
The user equipment 10 comprises a memory 502 configured to have the
multiple sets of power control parameters stored thereon. The multiple sets of power
control parameters may comprise a specific set of power control parameters to apply for
one or more subframes, and wherein the indication indicates a subframe comprised in
the one or more subframes.
The user equipment 10 further comprises a receiver 501 configured to receive,
from the radio network node 12, an indication indicating a set of power control
parameters out of the stored multiple sets of power control parameters. The set of
power control parameters may, as stated above, comprise at least one of: a maximum
transmit power; a target received power, a value indicating percentage of a pathloss that
is to be taken into account when determining transmit power, a power offset value, and
a power command value. In some embodiments the receiver 501 is further configured to
receive the multiple sets of power control parameters from the radio network node 12
during configuration of the user equipment 10. Then the user equipment 10 is
configured to store the multiple sets of power control parameters at the memory 502.
The user equipment 10 also comprises a determining circuit 503 configured to
determine a transmit power based on the indicated set of power control parameters. The
receiver 501 may be configured to receive an uplink grant message comprising the
indication. The indication may be a pointer in a list of sets of power control parameters,
and wherein the pointer indicates in the list what set of power control parameter to apply
in the determining circuit 503. The determining circuit 503 may in some embodiments be
configured to determine transmit power using a formula defined as
P (i),
CMAX,c
P (i)=min
PUSCH,c
10log (M (i))+P (j)+a (j) PL +D (i)+f (i)
PUSCH,c O_PUSCH,c c c TF,c c
where:
P (i) is the transmit power for subframe i over a physical uplink shared
PUSCH,c
channel;
P (i)
is the maximum transmit power;
CMAX,c
6788864_4.doc
M (i)
is a bandwidth of a Physical Uplink Shared Channel resource
PUSCH,c
assignment expressed in number of resource blocks;
P (j) is the target received power;
O_PUSCH,c
a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1}
, and is the value indicating percentage of
a pathloss that is to be taken into account when determining transmit power;
PL is the downlink path loss estimate;
D (i) is the power offset value; and
TF,c
f (i) is the power command value.
The receiver 501 may further be configured to receive an accumulative power
command. Then the determining circuit 503 may be configured to accumulate the
accumulative power command with a previously used power command, and to
accumulate differently for different sets of power control parameters.
In addition, the user equipment 10 may comprise an applying circuit 504
configured to apply the determined transmit power for a transmission to the radio
network node 12. The applying circuit 504 may be connected to a Power Amplifier
(PA) 505 providing the transmit power when transmitting the transmissions, such as
reference signals and/or data transmissions, via a transmitter 506.
The embodiments herein for applying transmit power for transmissions in the
radio communications network may be implemented through one or more processors,
such as a processing circuit 507 in the user equipment 10 depicted in Fig. 5, together
with computer program code for performing the functions and/or method actions of the
embodiments herein. The program code mentioned above may also be provided as a
computer program product, for instance in the form of a data carrier carrying computer
program code for performing embodiments herein when being loaded into the user
equipment 10. One such carrier may be in the form of a CD ROM disc. It is however
feasible with other data carriers such as a memory stick. The computer program code
may furthermore be provided as pure program code on a server and downloaded to the
user equipment 10. Those skilled in the art will also appreciate that the various “circuits”
described may refer to a combination of analog and digital circuits, and/or one or more
processors configured with software and/or firmware (e.g., stored in memory) that, when
executed by the one or more processors, perform as described above. One or more of
these processors, as well as the other digital hardware, may be included in a single
application-specific integrated circuit (ASIC), or several processors and various digital
6788864_4.doc
hardware may be distributed among several separate components, whether individually
packaged or assembled into a system-on-a-chip (SoC).
The method actions in the radio network node 12, exemplified above as the radio
base station 12’ in the figures, for controlling transmit power of the user equipment 10 in
the radio communications network, according to some general embodiments will now be
described with reference to a flowchart depicted in Fig. 6. The radio network node 12
serves the user equipment 10 in the radio communications network. The steps do not
have to be taken in the order stated below, but may be taken in any suitable order.
Actions merely performed in some embodiments are marked as dashed boxes.
Action 601. The radio network node 12 configures the user equipment 10 with
the multiple sets of power control parameters by sending the multiple sets to the user
equipment 10.
Action 602. The radio network node 12 determines the set of power control
parameters to be used by the user equipment 10 for determining transmit power of the
user equipment 10. The set of power control parameters may comprises at least one of:
a maximum transmit power; a target received power, a value indicating percentage of a
pathloss that is to be taken into account when determining transmit power, a power
offset value, and a power command value. For example, the radio network node 12 may
analyse an interference situation in the cell 11 serving the user equipment 10 and/or an
interference situation in a cell neighbouring the cell 11. Based on this analysis the radio
network node 12 determines the set of power control parameters. The interference
situation may be discovered by reduced SNR values for certain subframes or similar.
The analysis may indicate eNB-eNB interference, adjacent carrier interference, a UE-UE
interference, or similar.
Action 603. The radio network node 12 may retrieve the indication indicating the
determined power control parameter from a memory at the radio network node 12.
Action 604. The radio network node 12 transmits the indication to the user
equipment 10. As stated above, the indication indicates the set of power control
parameters out of multiple sets of power control parameters stored at the user
equipment 10. The radio network node 12 thereby controls the transmit power of the
user equipment 10. The multiple sets of power control parameters may e.g. be
comprised in an indexed list stored at the radio network node 12 as well as at the user
equipment 10, and wherein the indication is an index in the list. In some embodiments
the multiple sets of power control parameters comprises a specific set of power control
6788864_4.doc
parameters to apply for one or more subframes, and the indication indicates a subframe
comprised in the one or more subframes. For example, different subframes may have
different configured power control parameters at the user equipment 10. Since the radio
network node 12 knows this power control parameter/s for the different subframes, also
configured at the radio network node 12, the radio network node 12 schedules a
subframe with e.g. no restriction on transmit power, to the user equipment 10. The user
equipment 10 then determines the transmit power based on the configured power
control parameters of that subframe.
In some embodiments the radio network node 12 serves the user equipment 10
in the cell 11, also known as serving cell, and the one or more subframes is a subframe
or subframes used for downlink transmissions in the cell 11 or a cell neighbouring the
cell 11. These subframes may then be affected by so called eNodeB-to-eNodeB
interference in addition to UE-to-UE interference, and this is taken into consideration
when determining the set of power control parameters. Furthermore, the indication may
be transmitted for granted subframes. The granted subframes experiences adjacent
channel interference. This may indicate that the user equipment 10 should transmit with
no transmit power restrictions or with power restrictions e.g. based on relevance of the
transmission data.
The indication may be comprised in an uplink grant message. Then, the
indication may be a pointer in a list of sets of power control parameters. The pointer
indicates in the list what set of power control parameter to apply by the user equipment
when determining transmit power e.g. an index as stated above.
Fig. 7 is a block diagram depicting a radio network node for controlling a transmit
power of the user equipment 10 in the radio communications network according to some
embodiments herein. The radio network node 12 is configured to serve the user
equipment 10 in the radio communications network.
The radio network node 12 comprises a determining circuit 701 configured to
determine the set of power control parameters to be used by the user equipment 10 for
determining transmit power of the user equipment 10. The determining circuit 701 may
be configured to analyse an interference situation in the cell 11 serving the user
equipment 10 and/or an interference situation in a cell neighbouring the cell 11. The cell
neighbouring the cell 11 may be served by the radio network node 12 or a
neighbouring network node 120.
6788864_4.doc
The radio network node 12 further comprises a transmitter 702 configured to
transmit the indication to the user equipment 10. The indication indicates the set of
power control parameters out of the multiple sets of power control parameters stored at
the user equipment 10. The transmit power of the user equipment 10 is thereby
controlled by the radio network node 12. The multiple sets of power control parameters
may comprise a specific set of power control parameters to apply for one or more
subframes. The indication may then indicate a subframe comprised in the one or more
subframes. In some embodiments the transmitter 702 is configured to transmit an uplink
grant message comprising the indication. The indication may be a pointer in a list of sets
of power control parameters, and the pointer indicates in the list what set of power
control parameter to apply by the user equipment 10 when determining transmit power.
The indication may be transmitted for granted subframes, which granted subframes
experiences adjacent channel interference. This may be determined at the determining
circuit 701.
Furthermore, the radio network node 12 may comprise a configuring circuit
703 adapted to configure the user equipment 10 with the multiple sets of power control
parameters by sending the multiple sets to the user equipment 10 over the transmitter
702 but also receiving data, such as data signals from the user equipment indicating
interference, transmit power or similar, over a receiver 704. The radio network node 12
may further be configured to serve the user equipment 10 in the cell 11, and the one or
more subframes is a subframe or subframes used for downlink transmissions in the cell
11 or a cell neighbouring the cell 11. In some embodiments the set of power control
parameters comprises at least one of: a maximum transmit power; a target received
power, a value indicating percentage of a pathloss that is to be taken into account when
determining transmit power, a power offset value, and a power command value.
The radio network node may further comprise a retrieving circuit 705
configured to retrieve the indication, e.g. retrieving the indication from a memory 706.
The indication indicates the determined set of power control parameters from the
memory 706 at the radio network node 12.
The embodiments herein for controlling the transmit power of the user equipment
in the radio communications network may be implemented through one or more
processors, such as a processing circuit 707 in the radio network node 12 depicted in
Fig. 7, together with computer program code for performing the functions and/or method
actions of the embodiments herein. The program code mentioned above may also be
provided as a computer program product, for instance in the form of a data carrier
6788864_4.doc
carrying computer program code for performing embodiments herein when being loaded
into the radio network node 12. One such carrier may be in the form of a CD ROM disc.
It is however feasible with other data carriers such as a memory stick. The computer
program code may furthermore be provided as pure program code on a server and
downloaded to the radio network node 12. Those skilled in the art will also appreciate
that the various “circuits” described may refer to a combination of analog and digital
circuits, and/or one or more processors configured with software and/or firmware (e.g.,
stored in memory) that, when executed by the one or more processors, perform as
described above. One or more of these processors, as well as the other digital
hardware, may be included in a single application-specific integrated circuit (ASIC), or
several processors and various digital hardware may be distributed among several
separate components, whether individually packaged or assembled into a system-on-a-
chip (SoC).
It should be noted that the embodiments herein may be combined in any way.
Embodiments herein are described for uplink data channel but may also be applied for
another uplink transmission using power controls, e.g. Physical uplink control channel
(PUCCH) and uplink sounding reference signal. In the drawings and specification, there
have been disclosed exemplary embodiments. However, many variations and
modifications can be made to these embodiments. Accordingly, although specific terms
are employed, they are used in a generic and descriptive sense only and not for
purposes of limitation, the scope of the embodiments herein being defined by the
following claims.
6788864_4.doc
Claims (27)
1. A method in a user equipment for determining a transmit power to be used by the user equipment when transmitting in a radio communications network, wherein the user equipment is served by a radio network node in the radio 5 communications network, the method comprising: - receiving multiple sets of power control parameters from the radio network node during configuration of the user equipment, wherein the multiple sets of power control parameters are stored at the user equipment, wherein the multiple sets of power control parameters comprise a specific set of power control 10 parameters to apply for one or more subframes; - receiving, from the radio network node, an indication indicating the set of power control parameters out of the multiple sets of power control parameters, wherein the indication indicates a subframe comprised in the one or more subframes; - determining the transmit power for the indicated subframe based on the 15 indicated set of power control parameters.
2. A method according to claim 1, wherein the set of power control parameters comprises at least one of: a maximum transmit power; a target received power, a value indicating percentage of a pathloss that is to be taken into account when 20 determining transmit power, a power offset value, and a power command value.
3. A method according to claim 2, wherein the determining comprises to determine transmit power using a formula defined as P (i), CMAX,c P (i)=min PUSCH,c 10log (M (i))+P (j)+a (j) PL +D (i)+f (i) 10 PUSCH,c O_PUSCH,c c c TF,c c where: P (i) is the transmit power for subframe i over a physical uplink shared PUSCH,c channel; P (i) is the maximum transmit power; CMAX,c M (i) 30 is a bandwidth of a Physical Uplink Shared Channel resource PUSCH,c assignment expressed in number of resource blocks; P (j) is the target received power; O_PUSCH,c 6788864_4.doc a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1} , and is the value indicating percentage of a pathloss that is to be taken into account when determining transmit power; PL is the downlink path loss estimate; D (i) is the power offset value; and TF,c f (i) 5 is the power command value.
4. A method according to any one of claims 1-3, wherein the receiving further comprises to receive an accumulative power command, and the determining comprises to accumulate the accumulative power command with a previously 10 used power command, and wherein different accumulations are done for different sets of power control parameters.
5. A method in a radio network node for controlling a transmit power of a user equipment in a radio communications network, wherein the radio network node 15 serves the user equipment in the radio communications network, the method comprising: - configuring the user equipment with multiple sets of power control parameters by sending the multiple sets to the user equipment, wherein the multiple sets of power control parameters comprise a specific set of power control parameters to 20 apply for one or more subframes; and - transmitting an indication to the user equipment, wherein the indication indicates the set of power control parameters out of the multiple sets of power control parameters stored at the user equipment, thereby controlling the transmit power of the user equipment, wherein the indication indicates a subframe 25 comprised in the one or more subframes.
6. A method according to claim 5, wherein the radio network node serves the user equipment in a cell and the one or more subframes is a subframe or subframes used for a downlink transmission in the cell or a cell neighbouring the cell.
7. A method according to claim 5 or claim 6, wherein the set of power control parameters comprises at least one of: a maximum transmit power; a target received power, a value indicating percentage of a pathloss that is to be taken 6788864_4.doc into account when controlling transmit power, a power offset value, and a power command value.
8. A method according to any one of claims 5-7, further comprising 5 - retrieving the indication indicating the set of power control parameters from a memory at the radio network node.
9. A method according to any one of claims 5-8, wherein the configuring comprises to analyse an interference situation in a cell serving the user equipment and/or 10 an interference situation in a cell neighbouring the cell.
10. A method according to any one of claims 5-9, wherein the indication is transmitted for granted subframes, which granted subframes experiences adjacent channel interference.
11. A user equipment for determining a transmit power to be used by the user equipment when transmitting in a radio communications network, wherein the user equipment is configured to be served by a radio network node in the radio communications network, the user equipment comprising: 20 a receiver configured to receive multiple sets of power control parameters from the radio network node during configuration of the user equipment, and to receive an indication from the radio network node, wherein the multiple sets of power control parameters comprise a specific set of power control parameters to apply for one or more subframes, wherein the indication indicates the set of 25 power control parameters out of the multiple sets of power control parameters, and wherein the indication indicates a subframe comprised in the one or more subframes; a memory configured to have the multiple sets of power control parameters stored thereon; and 30 a determining circuit configured to determine a transmit power for the indicated subframe based on the indicated set of power control parameters.
12. A user equipment according to claim 11, wherein the set of power control parameters comprises at least one of: a maximum transmit power; a target 35 received power, a value indicating percentage of a pathloss that is to be taken 6788864_4.doc into account when determining transmit power, a power offset value, and a power command value.
13. A user equipment according to claim 12, wherein the determining circuit is 5 configured to determine transmit power using a formula defined as P (i), CMAX,c P (i)=min PUSCH,c 10log (M (i))+P (j)+a (j) PL +D (i)+f (i) 10 PUSCH,c O_PUSCH,c c c TF,c c where: P (i) is the transmit power for subframe i over a physical uplink shared PUSCH,c 10 channel; P (i) is the maximum transmit power; CMAX,c M (i) is a bandwidth of a Physical Uplink Shared Channel resource PUSCH,c assignment expressed in number of resource blocks; P (j) is the target received power; O_PUSCH,c a ˛{0,0.4,0.5,0.6,0.7,0.8,0.9,1} 15 , and is the value indicating percentage of a pathloss that is to be taken into account when determining transmit power; PL is the downlink path loss estimate; D (i) is the power offset value; and TF,c f (i) is the power command value.
14. A user equipment according to any one of claims 11-13, wherein the receiver is further configured to receive an accumulative power command, and the determining circuit is configured to accumulate the accumulative power command with a previously used power command, and to accumulate differently 25 for different sets of power control parameters.
15. A radio network node for controlling a transmit power of a user equipment in a radio communications network, wherein the radio network node is configured to serve the user equipment in the radio communications network, the radio 30 network node comprising: a transmitter configured to transmit an indication to the user equipment; 6788864_4.doc a configuring circuit configured to configure the user equipment with multiple sets of power control parameters by sending the multiple sets to the user equipment over the transmitter, wherein the multiple sets of power control parameters comprise a specific set of power control parameters to apply for one 5 or more subframes; wherein the indication indicates the set of power control parameters out of the multiple sets of power control parameters stored at the user equipment, thereby controlling the transmit power of the user equipment , wherein the indication indicates a subframe comprised in the one or more subframes.
16. A radio network node according to claim 15, wherein the radio network node is configured to serve the user equipment in a cell and the one or more subframes is a subframe or subframes used for a downlink transmission in the cell or a cell neighbouring the cell.
17. A radio network node according to claim 15 or claim 16, wherein the set of power control parameters comprises at least one of: a maximum transmit power; a target received power, a value indicating percentage of a pathloss that is to be taken into account when controlling transmit power, a power offset 20 value, and a power command value.
18. A radio network node according to any one of claims 15-17, further comprising a retrieving circuit configured to retrieve the indication indicating the determined set of power control parameters from a memory at the radio network 25 node.
19. A radio network node according to any one of claims 15-18, wherein the configuring circuit is configured to analyse an interference situation in a cell serving the user equipment and/or an interference situation in a cell 30 neighbouring the cell.
20. A radio network node according to any one of claims 15-19, wherein the indication is transmitted for granted subframes, which granted subframes experiences adjacent channel interference. 6788864_4.doc
21. A method according to claim 1 or claim 5, wherein the indication explicitly indicates the indicated subframe and the explicitly indicated subframe implicitly indicates the set of power control parameters. 5
22. A method according to claim 5, wherein the method comprises selectively transmitting to the user equipment an accumulative power command to accumulate the accumulative power command with a previously transmitted power command, wherein different accumulations are done for different sets of power control parameters.
23. A radio network node according to claim 15, wherein the transmitter is configured to selectively transmit an accumulative power command to accumulate the accumulative power command with a previously transmitted power command, wherein different accumulations are done for different sets of 15 power control parameters.
24. A method according to claim 1, wherein the multiple sets of power control parameters comprises different sets of power control parameters to respectively apply for different subframes.
25. A method according to claim 1 or claim 5, the method being substantially as hereinbefore described with reference to the accompanying drawings.
26. A user equipment according to claim 11, the user equipment being substantially 25 as hereinbefore described with reference to the accompanying drawings.
27. A radio network node according to claim 15, the radio network node being substantially as hereinbefore described with reference to the accompanying drawings. 6788864_4.doc 12,12'
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| PCT/SE2012/050458 WO2013165286A1 (en) | 2012-05-03 | 2012-05-03 | Radio network node, user equipment and methods therein |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ701508A NZ701508A (en) | 2016-11-25 |
| NZ701508B2 true NZ701508B2 (en) | 2017-02-28 |
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