Title of Invention

A BASE STATION APPARATUS AND A METHOD FOR RADIO COMMUNICATIONS USING AN ORTHOGONAL FREQUENCY DIVISION MULTIPLEXING SYSTEM

Abstract A base station (10) performs bi-directional radio communication with a terminal station apparatus by using a time division communication frame consisting of a first region having a predetermined open loop cycle and a second region having an open loop cycle shorter than the first region. A level detection block (21) detects a reception level of an uplink slot arranged in the second region. A transmission diversity block (14) diversity-transmits a downlink transmission signal allocated to a downlink slot corresponding to the aforementioned uplink slot in accordance with the detection result of the reception level. Thus, it is possible to enhance the improvement effect of the reception quality by the transmission diversity without lowering the transmission efficency.
Full Text DESCRIPTION
BASE STATION APPARATUS AND RADIO COMMUNICATION METHOD
Technical Field
The present invention relates to a base station
apparatus that performs bi-directional radio
communications with terminal stations using a TDD (Time
Division Duplex) system in which time slots with the same
radio frequency are used to communicate alternately over
the uplink and downlink, and more particularly, to a base
station apparatus that performs communications using an
OFDM (Orthogonal Frequency Division Multiplexing)
system.
Background Art
As a duplex system in a mobile communication system
using CDMA (Code Division Multiple Access) , a TDD system
is conventionally known. The TDD system uses the same
frequency band for transmission and reception, called
a ping-pong system, and is a system where time slots with
the same radio frequency are used to communicate
alternately over the uplink and downlink.
FIG.1 illustrates an example of a configuration of
a communication frame in the TDD system. The
communication frame illustrated in FIG.l is divided into
a plurality of times slots . In this communication frame,
downlink time slots (downlink slots 1 to n) are configured
in the first half of the frame, while uplink time slots
(uplink slots 1 to n) are configured in the latter half
of the frame. FIG.1 illustrates an example where the
uplink slots 1 to n are assigned corresponding uplink
bursts 1 to n, while the downlink slots 1 to n are assigned
corresponding downlink bursts 1 to n.
When a base station performs radio communications
with terminal station apparatuses using thus configured
communication frames, each terminal station apparatus
is assigned an uplink slot and downlink slot contained
in the communication frame. Based on a timing signal
shown in FIG.l, the base station apparatus switches
between transmission processing and reception processing.
A terminal station apparatus performs transmission
processing and reception processing at timings of an
uplink slot and downlink slot assigned to the terminal
station apparatus, respectively.
Structures of an uplink burst and downlink burst
will be described below with reference to FIGs.2 and 3.
FIG. 2 is a diagram illustrating a structure of a downlink
burst, and FIG.3 is a diagram illustrating a structure
of an uplink burst. At a beginning of the downlink burst
is disposed a propagation path estimation preamble that
is a known signal and used in propagation path estimation.
The propagation path estimation preamble is followed by-
data (downlink data #1 and #2) to a terminal station.
Downlink bursts are transmitted at respective
predetermined timings from a base station apparatus, and
therefore, never collide with one another . Accordingly,
the downlink burst is not provided with a guard time.
Meanwhile, as shown in FIG.3, the uplink burst is
provided at its beginning with a guard time to prevent
the collision with an adjacent burst, and the guard time
is followed by a sync/AGC preamble used in detection of
synchronization and AGC (Automatic Gain Control). The
sync/AGC preamble is followed by a propagation path
estimation preamble that is a known signal and used in
propagation path estimation. The propagation path
estimation preamble is followed by data (uplink data #3
and #4) to the base station.
In the communication frame illustrated in FIG.1,
configuring downlink bursts collectively shifts a
reception timing of an uplink burst from a predetermined
reception timing, and thereby prevents the collision with
the downlink burst. In this way, since the need is
eliminated of providing a downlink burst with a guard
time, the rate of the guard time to the communication
frame is decreased to improve the transmission
efficiency.
In the mobile communication field, since the quality
of received signals significantly deteriorates due to
fading, the diversity processing is used to reduce the
deterioration in the quality of received signals due to
fading. The diversity processing is a technique of
preventing drops in power of received signalsona receiver
side, but in order for a communication terminal apparatus
such as a mobile station to implement the diversity, there
are limitations in processing capability,
miniaturization, etc. Therefore, transmission
diversity has been studied in order for a transmitter
side to implement the diversity which is originally to
be implemented on a receiver side.
The transmission diversity will be described which
is performed between a base station and terminal station
when the base station communicates with the terminal
station using communication frames shown in FIG.1. It
is assumed that each of the base station and terminal
station has an IFFT circuit, and performs OFDM
communications over both the uplink and downlink.
The base station receives uplink bursts using a
plurality of antenna elements, and detects received
levels for each antenna element. The detection of
received levels is performed for each subcarrier of a
received signal. Based on a result of detection of
received levels, the base station assigns a subcarrier
composing a downlink burst to an antenna element with
the highest received level with respect to the subcarrier.
Such transmission diversity has a premise that in
the TDD system, propagation path characteristics are
approximately the same over the downlink and the uplink.
Based on this premise, in the transmission diversity,
a downlink signal is transmitted from a branch with the
highest uplink received power, whereby it is aimed to
maximize the downlink received power in a terminal
station.
However, in the frame configuration where downlink
slots and uplink slots are respectively collected and
arranged, since an uplink slot is spaced apart from a
downlink slot (inother words, alarge time interval exists
between reception of an uplink slot and transmission of
a downlink slot), the channel condition at the time of
receiving the uplink slot is greatly different from the
channel condition at the time of receiving the downlink
slot. Accordingly, the premise that propagation path
characteristics are approximately the same over the
downlink and the uplink crumbles, and there arises a
problem that the capability of diversity of improving
the received quality deteriorates.
Disclosure of Invention
It is an object of the present invention to provide
a base station apparatus and radio communication method
enabling enhanced effects of improving received quality
due to transmission diversity without degrading the
transmission efficiency.
Brief Description of Drawings
FIG.1 is an example of a configuration of a
communication frame used in OFDM communications;
FIG.2 is a diagram illustrating a structure of a
downlink burst;
FIG.3 is a diagram illustrating a structure of an
uplink burst;
FIG.4 is a block diagram illustrating a
configuration of a base station according to a first
embodiment of the present invention;
FIG.5 is a diagram to explain an example of a slot
configuration of a communication frame used in the first
embodiment of the present invention;
FIG. 6 is a diagram illustrating simulation results
of the relationship between Eb/No(dB) and an error rate
in a terminal station;
FIG.7 is a diagram to explain an example of a slot
configuration of a communication frame used in a second
embodiment of the present invention;
FIG. 8 is a diagram to explain an example of a slot
configuration of a communication frame used in a third
embodiment of the present invention;
FIG. 9 is a diagram to explain an example of a slot
configuration of a communication frame used in a fourth
embodiment of the present invention;
FIG.10 is a block diagram illustrating a
configuration of a base station according to a fifth
embodiment of the present invention;
FIG.11 is a diagram to explain an example of a slot
configuration of a communication frame used in a sixth
embodiment of the present invention;
FIG.12 is a block diagram illustrating a
configuration of a base station according to a seventh
embodiment of the present invention;
FIG. 13 is a diagram illustrating transmission power
of a downlink burst for each subcarrier;
FIG.14 is a diagram illustrating received power of
the downlink burst in a terminal station; and
FIG. 15 is a block diagram illustrating a
configuration of a base station according to an eighth
embodiment of the present invention.
Best Mode for Carrying Out the Invention
The inventor of the present invention found out that
with attention focused on a slot configuration of a
communication frame (see FIG.1) in a TDD system in which
downlink slots and uplink slots are configured
collectively, configuring an uplink slot and downlink
slot adjacent to one another (i.e., decreasing an
open-loop period) improves effects of improving
communication quality due to transmission diversity on
bursts assigned to the slots configured adjacent to one
another. Further, the inventor of the present invention
found out that by setting a ratio of a second region to
the entire frame properly, an uplink burst and downlink
burst are configured adjacent to one another, and it is
thereby possible to suppress the deterioration of
transmission efficiency caused by a guard time needed
to be added to a downlink burst to a range of not affecting
the transmission efficiency required in a system.
In other words , it is a gist of the present invention
to provide a communication frame with a second region
with a short open-loop period, and perform diversity
combining on transmission signals assigned to slots of
the second region to transmit.
Embodiments of the present invention will be
specifically described below with reference to
accompanying drawings.
(First embodiment)
FIG. 4 is a block diagram illustrating a
configuration of base station 10 according to the first
embodiment of the present invention. In this embodiment
it is assumed that base station 10 performs radio
communications with terminal stations #1 to #n not shown.
It is further assumed that base station 10 performs
bi-directional communications with terminal stations #1
to #n using the TDD system. A case is explained as an
example where eachofbasestation 10 and terminal stations
#1 to #n is provided with an OFDM modulator and OFDM
demodulator (either is not shown), and OFDM
communications are performed over the uplink and
downlink.
In FIG.4 receiving section 19 performs
predetermined reception processing such as
downconverting and A/D conversion on a received signal
received from corresponding antenna element 17.
Receiving section 20 performs predetermined reception
processing such as downconverting and A/D conversion on
a received signal received from corresponding antenna
element 18. In addition, the received signals received
from antenna elements 17 and 18 are OFDM signals
transmitted from either of terminal stations #1 to #n.
Based on output signals from receiving sections 19
and 20, level detecting section 21 detects a received
level of each subcarrier composing the received OFDM
signal for each antenna . In other words, level detecting
section 21 detects received levels of subcarriers
composing the OFDM signal received from antenna 17 based
on the output signal from receiving section 19, while
detecting received levels of subcarriers composing the
OFDM signal received from antenna 18 based on the output
signal from receiving section 20.
Reception diversity section 22 refers to received
levels detected in level detecting section 21, and
performs diversity combining on received signals output
from receiving sections 19 and 20. Specifically,
reception diversity section 22 refers to a result detected
in level detecting section 21, and performs selective
combining of selecting a subcarrier with a higher level
as a received signal.
In addition, diversity combining in reception
diversity section 22 is not limited to the selective
combining. For example, reception diversity section 22
may shift phases of signals output from receiving sections
19 and 20 to be in phase for each subcarrier, perform
weighting on the in-phase received signals based on
respective received levels, and perform maximal-ratio
combining on the weighted signals. Further, reception
diversity section 22 may shift phases of signals output
from receiving sections 19 and 20 to be in phase for each
subcarrier, and perform equal-gain combining on the
in-phase received signals.
The received signals subjected to the diversity
combining in reception diversity section 22 are output
to reception buffer section 2 3 . Reception buffer section
23 performs processing such as FFT (Fast Fourier
Transform) on the output signal of reception diversity
section 22 to obtain received data. Reception buffer
section 23 further performs error detection on the
received data, and outputs received data with no error
detected therein as final received data to following
circuitry.
Base station 10 has sections for reception as
configured described above. A configuration of sections
for transmission will be described below.
Transmission buffer section 11 performs IFFT
(Inverse Fast Fourier Transform) on transmission data
to generate an OFDM signal, and holds the signal until
the time of receiving control to output from band assigning
section 13.
Timing generating section 12 generates a rectangle
timing signal with rising edges and falling edges, and
outputs the generated timing signal to band assigning
section 13. The timing signal is generated based on a
slot configuration of a communication frame predetermined
under the system.
Band assigning section 13 refers to the timing signal
output from timing generating section 12 (particularly,
by detecting the rising edge and falling edge), and
recognizes the slot configuration in the communication
slot. Then, based on the result of detection of received
levels in level detecting section 21, band assigning
section 13 assigns an uplink slot and downlink slot
configured at predetermined positions in the
communication frame to each of terminal stations #1 to
#n. Band assigning section 13 controls transmission
buffer section 11 according to the slot assignment, and
instructs the section 11 to output the OFDM signal held
in the section 11 to transmission diversity section 14
as a downlink burst.
Based on the result of detection of received levels
in level detecting section 21, transmission diversity
section 14 performs transmission diversity processing
on the downlink burst output from transmission buffer
section 11. In other words, transmission diversity
section 14 selects an antenna element with a higher
received level for each subcarrier, and outputs a signal
assigned to the subcarrier to a transmitting section
(transmitting section 15 or 16) corresponding to the
selected antenna. For example, with respect to
subcarrier S1 with predetermined frequency f1 of OFDM
signals output from antenna elements 17 and 18, when the
received level of the received signal from antenna element
17 is higher that from antenna element 18, transmission
diversity section 14 outputs subcarrier S1 with f 1 among
OFDM signals output from transmission buffer section 11
to transmitting section 15 corresponding to antenna
element 17 to transmit from antenna element 17.
Thus, in the OFDM signals, since propagation path
characteristics are different for each subcarrier, base
station 10 according to this embodiment performs the
transmission diversity for each subcarrier.
Transmitting sections 15 and 16 perform
predetermined radio transmission processing such as
upconverting and D/A conversion on output signals from
transmission diversity section 14. The signals thus
having undergone radio transmission processing are
transmitted from antenna element 17 or 18.
While base station 10 according to this embodiment
is provided with two antenna elements, i.e., antenna
elements 17 and 18, to perform diversity processing, the
present invention allows base station 10 to have a
plurality of antenna elements to perform diversity.
FIG. 5 is a diagram to explain an example of a slot
configuration of a communication frame used in the first
embodiment of the present invention. As illustrated in
FIG.5, in this embodiment, a general communication frame
in which downlink slots and uplink slots are collectively
configured is provided with an interval at which uplink
slots and downlink slots are configured so that uplink
and downlink slots are adjacent to each other.
Hereinafter, in the specification, the interval in a
communication frame at which uplink and downlink slots
are configured adjacent to each other is referred to as
a "second region" . Further, in the communication frame,
the other region except the second region is referred
to as a "first region". In an example shown in FIG.5,
the second region is composed of uplink slots #1 to #k
and downlink slots #1 to #k, while the first region is
composed of uplink slots #k+1 to #n and downlink slots
#k+1 to #n.
FIG.5 shows, as an example of configuring uplink
and downlink slots adjacent to each other, a case where
an uplink slot is configured immediately after a downlink
slot. In other words, in the second region of the
communication slot shown in FIG.5, an uplink slot for
a terminal station and a downlink slot for the terminal
station are configured as a pair of unit.
The operation of base station 10 with the above
configuration will be described below.
The operation of sections for reception in base
station 10 will be described first.
OFDM signals transmitted from terminal stations #1
to #n are received in antenna elements 17 and 18. The
OFDM signals received in antenna elements 17 and 18 are
subjected to predetermined radio reception processing
respectively in receiving sections 19 and 20, and output
to level detecting section 21 and reception diversity
section 22.
Level detecting section 21 detects received levels
for each subcarrier composing a received OFDM signal.
Results of the detection of received levels for each
subcarrier are output to reception diversity section 22,
transmission diversity section 14 and band assigning
section 13. Reception diversity section 22 refers to
input received levels, and performs diversity combining
for each subcarrier. Reception buffer section 23
performs FFT on the resultant of diversity combining to
obtain received data.
Next, the operation of sections for transmission
in base station 10 will be described next.
Timing generating section 12 generates a rectangle
timing signal composed of rising edges and falling edges,
according to the slot configuration as shown in FIG.5.
The timing signal is generated, for example, as shown
in FIG.5, so that each rising edge indicates a switching
timing from an uplink slot to a downlink slot, while each
falling edge indicates a switching timing from a downlink
slot to an uplink slot.
Band assigning section 13 assigns downlink bursts
(downlink burst 1 to n) respectively for terminal stations
#1 to into slots in the communication frame, corresponding
to the result of the detection of received levels in level
detecting section 21. The configuration of slots is set
in advance under the system, and for example, the slots
are configured as shown in FIG.5.
The slot assignment for downlink burst is performed
in consideration of effects on communication quality
caused by difference in configuration method between
slots configured in the second region and slots configured
in the other region except the second region, and
particularly, in consideration of effects on
communication quality of the downlink channel in
controlling the downlink channel based on channel
conditions (for example, received levels) on the uplink
channel, (i.e., performing open-loop control). In the
open-loop control, predetermined processing is performed
on a downlink transmission signal based on an estimation
result of the uplink channel condition. For example,
in transmission diversity processing that is an example
of open-loop control, as described above, downlink bursts
are subjected to diversity combining based on received
levels of uplink slots.
In other words, in the second region, since a
downlink slot is configured immediately after an uplink
slot, a time (in the specification, also referred to as
an "open-loop period") elapsed between reception of an
uplink slot and transmission of a downlink slot
corresponding to the received uplink slot (in other words ,
a downlink slot on the same channel as of the received
uplink slot) is shorter than an open-loop period in the
first region. Accordingly, in performing open-loop
control, assigning a slot in the second region allows
higher accuracy in performing predetermined processing
(for example, diversity combining) on a downlink
transmission signal than assigning a slot in the first
region.
Thus, by performing open-loop control using a slot
configured in the second region, it is possible to use
channel estimation results with higher accuracy than
performing communications using a slot assigned to the
first region. It is thus possible to control signals
to transmit over the downlink appropriately. For example,
when the transmission diversity is performed, the
diversity effect can be improved.
Accordingly, band assigning section 13 refers to
received levels detected in level detecting section 21,
and assigns the second region preferentially to a terminal
station of low received level (i.e., poor channel
condition), whereby it is possible to improve the
communication quality of the terminal station in poor
channel condition.
Meanwhile, in order to assign slots to the second
region, since uplink and downlink slots are adjacent to
each other, the need arises of providing a downlink slot
with a guard time. Accordingly, an increased ratio of
the second region to the communication frame may cause
the transmission efficiency to deteriorate. Therefore,
the number of slots (the number of channels) configured
in the second region is determined corresponding to the
transmission efficiency. For example, when it is assumed
that a frame length is 2 ms, a guard time is 4µs, and
slots corresponding to five channels (in other words,
five slots for each of uplink and downlink channels , i.e.,
total 10 slots) are configured in the second region, an
increase in guard time is 5x µ 4s=20 µ s, which is
one-thousandth of the frame length, 2 ms. Thus, it is
possible to suppress the deterioration in transmission
efficiency in the entire frame caused by providing the
second region to an extremely small extent.
Band assigning section 13 controls transmission
buffer section 11 according to the slot assignment for
each terminal as described above. For example, when a
communication frame is configured as shown in FIG.5, the
section 13 detects afirstrisingedgeofthetimingsignal,
and performs control for outputting downlink burst #1
at a timing of detecting the rising edge. In this way,
a second slot from the beginning (left end viewed in the
figure) of a frame is assigned the downlink burst.
Subsequently, downlink bursts #2 to #n are output from
transmission buffer section 11 at predetermined timings
in the same way as in the control of downlink burst #1.
The downlink bursts output from transmission buffer
section 11 are subjected to transmission diversity
processing in transmission diversity section 14, then
to predetermined radio transmission processing in
transmitting section 15 or 16, and transmitted from
corresponding antenna element 17 or 18.
FIG.6 illustrates simulation results of the
relationship between Eb/No(dB) measured in base station
10 as described above and an error rate in a terminal
station. Simulation conditions are as described below.
PDU size: 54 BYTES;
FFT sample rate: 20MHz;
Guard interval length: 800ns
Frame length: 2ms;
Modulation scheme: 16AM;
Error correction: Convolutional coding/Viterbi
decoding (where the constraint length is 7 and coding
rate is 9/16);
Delay deviation: 150ns; and
Maximum Doppler frequency: 50Hz.
In FIG.6, black squares indicate simulation results
of the case of using the present invention (inother words,
a communication frame is provided with the second region) ,
black circles indicate simulation results of the case
of using a conventional base station (the case of
performing transmission diversity) , and black triangles
indicate simulation results of the case of using a
conventional base station (the case of not performing
transmission diversity).
Thus, the simulation results of the present
invention show great improvements in Eb/No needed to
obtain a predetermined error rate, as compared to the
simulation results of the case of performing conventional
transmission diversity. For example, when the error rate
in a terminal station is 10-2, Eb/No is improved by about
1.5dB.
As described above, according to this embodiment,
a communication frame is provided with a second region
having a short open-loop period and transmission signals
assigned to slots in the second region are subjected to
diversity combining, whereby it is possible to improve
the diversity effect with the transmission efficiency
hardly degraded.
(Second embodiment)
This embodiment is a modification of the first
embodiment, and provides a different communication frame
configuration from that in the first embodiment. FIG.7
is a diagram to explain an example of a slot configuration
of a communication frame used in the second embodiment
of the present invention. As shown in FIG.7, in the
communication frame used in this embodiment, downlink
slots except slots assigned to the second region are
configured collectively at a beginning portion of the
frame, while uplink slots except slots assigned to the
second region are configured collectively at an end
portion of the frame. The second region is sandwiched
between thus collectively configured downlink slots and
uplink slots.
Thus, in this embodiment, downlink slots except
slots assigned to the second region are configured
collectively at a beginning portion of a frame, while
uplink slots except slots assigned to the second region
are configured collectively at an end portion of the frame.
In this way, an interval between the uplink slot and a
downlink slot in the next frame is shorter than in the
frame configuration shown in FIG.5. Accordingly, when
the channel condition is estimated using an uplink slot
of a last frame and based on the estimation result,
transmission diversity is performed, it is possible to
further enhance the effect of improving the received
quality due to diversity, as compared to the case
illustrated in the first embodiment.
(Third embodiment)
This embodiment is a modification of the first
embodiment, and provides a different slot configuration
in the second region from that in the first embodiment.
FIG.8 is a diagram to explain an example of the slot
configuration of a communication frame used in the third
embodiment of the present invention. As shown in FIG.8,
in the second region of the communication frame used in
this embodiment, among slots configured in the second
region, uplink slots are collectively configured at the
first half of the second region, while downlink slots
are collectively configured at the latter half of the
second region.
The number of slots configured in the second region
is predetermined in advance under the system so that a
time interval between an uplink slot in the second region
and a downlink slot corresponding to the uplink slot is
shorter than a time interval between an uplink slot out
of the second region and a downlink slot corresponding
to the uplink slot. It is preferable to set the number
of slots configured in the second region so as to
sufficiently obtain the effect of improving the
communication quality in a terminal station due to the
transmission diversity. For example, when a burst length
is 24µS, assuming five uplink slots and five downlink
slots are configured in the second region results in the
time interval of 12 µs between anuplinkslot in the second
region and a downlink slot corresponding to the uplink
slot. 120µs is 1/20 of the frame length (2ms), and is
adequately short to obtain the effect of improving the
received quality due to the transmission diversity.
Thus, in this embodiment, since uplink slots and
downlink slots are configured separately and collectively
in the second region, it is possible to decrease the number
of switching processing times between the transmission
and reception processing in a predetermined time as
compared to the first embodiment. Further, it is
possible to perform the switching processing at a lower
rate than in the first embodiment. It is thereby possible
to reduce the power consumption required for the switching
processing between the transmission and reception
processing and to miniaturize an apparatus.
Inthefirstand second embodiments , all the downlink
bursts contained in the second region need to be provided
with a guard time. In this embodiment, providing only
a downlink burst at the beginning of the second region
with a guard time is capable of preventing the collision
of bursts. Therefore, by using the communication frame
in this embodiment, it is possible to further prevent
decreases in the transmission efficiency as compared to
cases illustrated in the first and second embodiments.
(Fourth embodiment)
This embodiment is a modification of the third
embodiment, provides a guard interval between an interval
at which uplink slots are collectively configured in the
second region and an interval at which downlink slots
are collectively configured in the second region, and
in this respect, is different from the third embodiment.
FIG. 9 is a diagram to explain an example of a slot
configuration of a communication frame used in the fourth
embodiment of the present invention. As illustrated in
FIG.9, in the second region of the communication frame
used in this embodiment, as in the third embodiment, among
slots configured in the second region, uplink slots are
collectively configured at the first half of the second
region, while downlink slots are collectively configured
at the latter half of the second region. A guard interval
to which any burst for transmitting information is not
assigned is provided between the first half of the second
region in which uplink slots are collectively configured
and the latter half of the second region in which downlink
slots are collectively configured.
Thus, in this embodiment, by providing a guard
interval between the first half of the second region in
which uplink slots are collectively configured and the
latter half of the second region in which downlink slots
are collectively configured, it is possible to perform
the switching processing between the transmission and
reception processing at a lower rate than in the third
embodiment. It is thereby possible to further reduce
the power consumption required for the switching
processing between the transmission and reception
processing and to miniaturize an apparatus.
(Fifth embodiment)
This embodiment is a modification of the first
embodiment, and it is a feature of this embodiment to
preferentially assign a signal with a high priority such
as a control signal and repeat signal to the second region.
FIG.10 is a block diagram illustrating a configuration
of base station 70 according to the fifth embodiment of
the present invention. In addition, in FIG.10, the same
structural elements as in FIG.4 are assigned the same
reference numerals to omit detailed descriptions thereof .
Further, a communication frame used in this embodiment
is the same as that illustrated in FIG.5.
The signal with a high priority is such a signal
that requires a high error rate, and for example, includes
a control signal and repeat signal. The signal(s) with
a high priority is defined under the system in advance,
and band assigning section 13 obtains information on the
signal with a high priority as channel information.
InFIG.10, selectingsection 71 refers to the channel
information held in band assigning section 13, selects
the signal with a high priority from transmission signals ,
and outputs the selected signal to transmission buffer
section 72. Selecting section 71 further outputs signals
except the signal with a high priority to transmission
buffer section 73.
Selecting section 74 refers to the channel
information, reads the signal with a high priority from
transmission buffer section 72, and assigns the signal
to a slot configured in the second slot of the
communication frame illustrated in FIG.5.
Band assigning section 13 assigns signals except
the signal with a high priority to slots configured at
the region except the second region. Band assigning
section 13 controls transmission buffer section 73
according to the slot assignment, so that the transmission
buffer section 73 outputs signals stored therein to
transmission diversity section 14 through selecting
section 74.
In this way, according to this embodiment, a signal
with a high priority (i.e. , signal requiring a high error
rate) is preferentially assigned to a slot configured
in the second region. Since the signal assigned to a
slot configured in the second region takes an advantage
of higher effect of improving the communication quality
due to the diversity, and it is possible to improve the
error rate of the signal with a high priority.
(Sixth embodiment)
This embodiment is a modification of the fourth
embodiment, and provides a different communication frame
configuration from that in the forth embodiment. FIG. 11
is a diagram to explain an example of a slot configuration
of a communication frame used in the sixth embodiment
of the present invention.
AsillustratedinFIG.1l, in the communication frame
used in this embodiment, a slot next to the second region
(i.e., a first one of the downlink slots collectively
configured at the region except the second region) is
defined as downlink slot X, while a last slot of the
communication frame (i.e. , a last one of the uplink slots
collectively configured at the region except the second
region) is defined as uplink slot X. The uplink slot
X configured in such a position is assigned burst X, and
the downlink slot X configured in such a position is
assigned burst X. In addition, the uplink slot X
corresponds to a target uplink slot as described in the
claims, while the downlink slot X corresponds to a target
downlink slot as described in the claims.
Bursts assigned to the downlink and uplink slots
X are selected based on channel quality information such
as RSSI and CRC detection result in band assigning section
13. For example, based on the channel quality
information, band assigning section 13 selects a burst
in the poorest channel condition from among bursts that
cannot be assigned to the second region.
According to the slot configuration as described
above, an interval between the uplink slot X and the
downlink slot X of the next frame is shorter than an
interval between an uplink slot assigned to the region
except the second region and a downlink slot in the next
frame corresponding to the uplink slot (for example, an
interval between uplink slot k+1 and downlink slot k+1
in the next frame). Accordingly, the channel condition
is estimated using uplink slot X of a last frame and based
on the estimation result, the transmission diversity is
performed, whereby using a slot (herein, slot X)
configured in the first region also enhances the effect
of improving the communication quality due to the
diversity.
(Seventh embodiment)
This embodiment is a modification of the first
embodiment, and it is a feature of this embodiment that
base station 90 performs transmission gain control in
addition to the transmission diversity. FIG.12 is a
block diagram illustrating a configuration of base
station 90 according to the seventh embodiment of the
present invention. In addition, in FIG.12, the same
structural elements as in FIG.4 are assigned the same
reference numerals to omit detailed descriptions thereof.
Further, a communication frame used in this embodiment
is the same as that illustrated in FIG.5.
In FIG.12, gain control section 91 calculates
transmission power based on the result in detection of
received levels of uplink slots in level detecting section
21, and amplifies a downlink burst output from
transmission buffer section 11 to the calculated
transmission power. Specifically, gain control section
91 compares a received level (hereinafter referred to
as a "detection level") detected in level detecting
section 21 with a received level (hereinafter referred
to as a "target level") indicative of a predetermined
target level. When the detection level is higher than
the target level, the section 91 decreases the
transmission power. On the other hand, when the
detection level is lower than the target level, the section
91 increases the transmission power.
Gain control section 91 performs transmission power
control for each subcarrier. In other words, the target
level is determined for each subcarrier, and by comparing
the target level with the detection level detected for
each subcarrier, the transmission power control is
performed for each subcarrier.
The transmission power control for each subcarrier
will be described with reference to FIGs.13 and 14.
FIG.13 is a diagram illustrating transmission power of
a downlink burst for each subcarrier, and FIG.14 is a
diagram illustrating received power of the downlink burst
illustrated in FIG.13 in a terminal station.
The downlink burst illustrated in FIG.13 has been
amplified ingaincontrol section 91 illustrated in FIG.12.
As illustrated in FIG.13, subcarriers in good channel
conditions (for example, third and eighth subcarriers
from the left viewed in the figure) are transmitted with
low transmission power, while subcarriers in poor channel
conditions ( for example, first and fifth subcarriers from
the left viewed in the figure) are transmitted with high
transmission power.
The downlink burst transmitted in this way is
received in a terminal station as illustrated in FIG.14.
As illustrated in FIG.14, each subcarrier is attenuated
on the transmission path, and is received with
approximately the same power as one another.
By thus performing the transmission power control
for each subcarrier, it is possible to hold the received
power of subcarriers at approximately the same level.
A subcarrier with a falling received level is considered
as a dominant factor that degrades the error rate of an
OFDM signal. Therefore, holding the received power of
subcarriers at approximately the same level prevents the
received level from falling down. It is thereby possible
to improve the error rate performance.
(Eighth embodiment)
This embodiment is a modification of the first
embodiment, and it is a feature of this embodiment that
base station 120 performs communications according to
an OFDM-CDMA (Code Division Multiple Access) system.
FIG.15 is a block diagram illustrating a configuration
of base station 120 according to the eighth embodiment
of the present invention. In addition, in FIG.15, the
same structural elements as in FIG.4 are assigned the
same reference numerals to omit detailed descriptions
thereof. Further, a communication frame used in this
embodiment is the same as that illustrated in FIG.5. The
OFDM-CDMA system is to perform CDMA communications in
multicarrier, and has a feature of multiplexing chips
assigned subcarriers, and thereby performing the
frequency division multiplexing.
In FIG. 15, spreading section 121 performs spreading
on a transmission signal output from transmission buffer
section 11, and thereby assigns each of subcarriers
composing the transmission signal to spreading chips.
The transmission signal with each subcarrier assigned
the chips is subjected to diversity combining in
transmission diversity section 14, and the resultant
radio signal is transmitted from corresponding antenna
element 17 or 18 through transmitting section 15 or 16,
respectively.
In this way, according to this embodiment, since
the diversity effect is improved on slots configured in
the second region, it is thereby possible to decrease
deterioration in the orthogonality between spreading
codes. As a result, since the number of spreading chips
usable in the frequency division multiplexing increases ,
it is possible to improve the transmission efficiency.
As described above, according to this embodiment,
a communication frame is provided with a second region
having a short open-loop period, and transmission signals
assigned to slots in the second region are subjected to
the diversity combining , whereby it is possible to improve
the diversity effect while hardly degrading the
transmission efficiency.
This application is based on the Japanese Patent
Application No.2001-121542 filed on April 19, 2001,
entire content of which is expressly incorporated by-
reference herein.
Industrial Applicability
The present invention is suitable for use in a base
station apparatus that performs bi-directional radio
communications with terminal stations using a TDD (Time
Division Duplex) system in which time slots with the same
radio frequency are used to communicate alternately over
the uplink and downlink, and more particularly, for use
in a base station apparatus that performs communications
using an OFDM (Orthogonal Frequency Division
Multiplexing) system.
We Claim:
1. A base station apparatus (10) adapted to perform radio communications
comprising:
a timing generating section (12) adapted to generate a timing signal
indicating a timing to assign an uplink slot and a timing to assign a
downlink slot to a communication frame having time slots; and
a band assigning section (13) adapted to assign downlink bursts to
time slots of a first region of said communication frame, said first
region comprising a plurality of collectively arranged downlink slots
followed by a plurality of collectively arranged corresponding uplink
slots,
the band assigning section (13) being further adapted to assign
downlink bursts to time slots of a second region of said communication
frame having a shorter open-loop period than said first region, said
open loop period being a time interval elapsed between reception of
an uplink slot and transmission of a corresponding downlink slot; and
said second region comprising collectively arranged uplink slots and
downlink slots that alternate such that an uplink slot is arranged
followed by the corresponding downlink slot.
2. The base station apparatus (10) as claimed in claim 1, comprising:
a section (21) adapted to detect a received level of an uplink slot in
the second region; and
a diversity section (14) adapted to perform diversity transmission on a
downlink transmission signal assigned to a downlink slot corresponding
to the uplink s!ot, corresponding to a result of detection of the
received level.
3. The base station apparatus as claimed in claim 2, wherein the second region
is disposed between downlink slots and uplink slots contained in the first
region.
4. The base station apparatus as claimed in claim 1, wherein uplink slots are
arranged in a region from the beginning to the center in the second region,
while downlink slots are arranged in a region from the center to the end in
the second region.
5. The base station apparatus as claimed in claim 4, wherein in the second
region, a guard interval is provided between the region in which the uplink
slots are arranged and the region in which the downlink slots are arranged.
6. The base station apparatus as claimed in claim 1, comprising
a section adapted to assign a transmission signal with a high priority to
a downlink slot contained in the second region.
wherein the diversity section (14) performs diversity transmission on the
transmission signal with a high priority, corresponding to a result of detection
of a received level of an uplink slot corresponding to the downlink slot
assigned the transmission signai with a high priority.
7. The bae station apparatus as claimed in claim 1, wherein a target downlink
slot contained in the first region is arranged at the beginning of the first
region, while a target uplink slot corresponding to the target downlink slot is
arranged at the end of a frame.
8. The base station apparatus as claimed in claim 1, comprising:
a section adapted to control transmission power of a downlink
transmission signal assigned to a downlink slot corresponding to an uplink
slot, corresponding to a result of detection of a received level of the uplink
slot.
9. The base station apparatus as claimed in claim 1, comprising:
a spreading section adapted to perform spreading on a downlink
transmission signal, and thereby assigning each of subcarriers
composing the downlink transmission signai to spreading chips.
10.The base station apparatus as claimed in claim 1, wherein a downlink
transmission signal is an OFDM signal obtained by performing IFFT on a
transmission signai.
11.A radio communication method for performing radio communications
comprising the steps of:
generating a timing signal indicating a timing to assign an uplink slot
and a timing to assign a downlink slot to a communication frame
having time slots;
assigning downlink bursts to time slots of a first and a second region
of said communication frame, the first region comprising a plurality of
collectively arranged downlink slots followed by a plurality of
collectively arranged corresponding uplink slots and the second region
having time slots having a shorter open-loop period than said first
region, said open-loop period being a time interval elapsed between
reception of an uplink slot and transmission of a corresponding
downlink slot; and
arranging uplink slots and downlink slots collectively in said second
region such that an uplink slot is arranged followed by the
corresponding downlink slot.
A base station (10) performs bi-directional radio communication with a terminal
station apparatus by using a time division communication frame consisting of a
first region having a predetermined open loop cycle and a second region having
an open loop cycle shorter than the first region. A level detection block (21)
detects a reception level of an uplink slot arranged in the second region. A
transmission diversity block (14) diversity-transmits a downlink transmission
signal allocated to a downlink slot corresponding to the aforementioned uplink
slot in accordance with the detection result of the reception level. Thus, it is
possible to enhance the improvement effect of the reception quality by the
transmission diversity without lowering the transmission efficency.

Documents:

IN-PCT-2002-1432-KOL-FORM-27.pdf

in-pct-2002-1432-kol-granted-abstract.pdf

in-pct-2002-1432-kol-granted-claims.pdf

in-pct-2002-1432-kol-granted-correspondence.pdf

in-pct-2002-1432-kol-granted-description (complete).pdf

in-pct-2002-1432-kol-granted-drawings.pdf

in-pct-2002-1432-kol-granted-examination report.pdf

in-pct-2002-1432-kol-granted-form 1.pdf

in-pct-2002-1432-kol-granted-form 18.pdf

in-pct-2002-1432-kol-granted-form 2.pdf

in-pct-2002-1432-kol-granted-form 3.pdf

in-pct-2002-1432-kol-granted-form 5.pdf

in-pct-2002-1432-kol-granted-gpa.pdf

in-pct-2002-1432-kol-granted-priority document.pdf

in-pct-2002-1432-kol-granted-translated copy of priority document.pdf


Patent Number 225478
Indian Patent Application Number IN/PCT/2002/1432/KOL
PG Journal Number 46/2008
Publication Date 14-Nov-2008
Grant Date 12-Nov-2008
Date of Filing 22-Nov-2002
Name of Patentee MATSUSHITA ELECTRIC INDUSTRIAL CO.LTD.
Applicant Address 1006 OAZA KADOMA, KADOMA SHI, OSAKA
Inventors:
# Inventor's Name Inventor's Address
1 SUDO HIROAKI 504 SAEDO-CHO, TSUZUKI KU, YOKOHAMA SHI, KANAGAWA 224 0054
PCT International Classification Number H04B 7/26
PCT International Application Number PCT/JP02/03753
PCT International Filing date 2002-04-16
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2001-121542 2001-04-19 Japan