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Claims  |
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I claim as my invention:
1. A fixed repeater for facilitating communication between a subscriber
unit and a central station when said subscriber unit is located in a zone
of weak signal strength wherein direct communication between said central
station and said subscriber unit cannot occur, comprising:
receiver means for receiving signals transmitted by said subscriber unit
and said central station;
transmitter means for transmitting signals to said subscriber unit and said
central station; and
control means, responsive to received signals, for recognizing a
transmission representing at least a call request from said subscriber
unit to said central station, and an absence of a channel grant from said
central station in response to said transmission representing at least
said call request from said subscriber unit, wherein said fixed repeater
repeats transmissions between said subscriber unit and said central
station by utilizing said receiver means and said transmitter means for
transmitting signals to said subscriber unit and said central station.
2. A fixed repeater for facilitating communication between a central
station and a subscriber unit, said subscriber unit having transmitting
means to request service of said repeater, comprising:
monitoring means in said fixed repeater for receiving signals from said
subscriber unit on a first channel;
receiver means for receiving a signal requesting said repeater to repeat
transmissions between said subscriber unit and said central station
transmitted by said subscriber unit on said first channel; and
control means responsive to said signal request of repeater service to
relay transmissions between said subscriber unit and said central station
by switching to an assigned channel already designated for said fixed
repeater.
3. A method for a repeater to facilitate communication between a subscriber
unit and a central station, comprising the steps of:
(a) receiving in said repeater signals transmitted by said subscriber unit;
(b) receiving in said repeater signals transmitted by said central station;
(c) controlling operation responsive to received signals for recognizing
transmission from said subscriber unit to said central station, and a lack
of response by said central station to said transmission from said
subscriber unit, wherein said repeater automatically transmits a signal
representing a call to said central station;
(d) receiving in said repeater a signal representing an answer from said
central station wherein said step (d) comprises receiving a message
representing at least a channel assignment from said central station, and
switching to assigned channels for communication with said subscriber unit
and said central station in response to said channel assignment; and
(e) operating to repeat transmissions between said subscriber unit and said
central station.
4. A method for a fixed repeater to facilitate communication between a
subscriber unit and a central station, comprising the steps of:
(a) monitoring in said fixed repeater signals received from said subscriber
unit on a first channel;
(b) receiving a request of repeater service signal transmitted by said
subscriber unit on said first channel wherein said request of repeater
service signal being received in step (b) comprises a signal requesting
said repeater to repeat transmissions between said subscriber unit and
said central station being received; and
(c) operating thereafter, to relay transmissions between said subscriber
unit and said central station by switching itself to an assigned channel
already designated for said fixed repeater.
5. A method for a repeater to facilitate communication in a communication
system between a subscriber unit and a central station, comprising the
steps of:
(a) monitoring in said repeater signals received from said subscriber unit
on a first channel;
(b) receiving a request of repeater service transmission from said
subscriber unit on said first channel requesting said repeater to repeat
transmissions;
(c) switching itself to at least one system predetermined channel for
communication with said subscriber unit and said central station in
response to said request of repeater service transmission;
(d) scanning by said subscriber unit to determine said at least one
predetermined channel; and
(e) repeating transmissions from said subscriber unit and said central
stations on said at least one system predetermined channel.
6. A method for a repeater to facilitate communication between a subscriber
unit and a central station via at least one control channel and at least
one communication channel, comprising the steps of:
(a) monitoring in said repeater a message representing at least a call
request from said subscriber unit to said central station on said control
channel;
(b) monitoring in said repeater a message representing at least a channel
assignment from said central station to said subscriber unit on said
control channel;
(c) detecting an absence of said message representing at least a channel
assignment from said central station and at least another message
representing at least a call request from said subscriber unit on said
control channel;
(d) transmitting a message representing at least a call request to said
central station in response to step (c) on said control channel;
(e) receiving in said repeater a signal representing an assignment from
said central station on said control channel for said subscriber unit to
communicate with said repeater on a first communication channel and for
said repeater to communicate with said central station on a second
communication channel; and
(f) repeating transmissions between said subscriber unit and said central
station.
7. A method for a repeater to facilitate communication in a communication
system between a subscriber unit and a central station via at least one
control channel and at least one system predetermined communication
channel, comprising the steps of:
monitoring, in said repeater, signals received from said subscriber unit on
said control channel;
receiving a signal requesting said repeater to repeat transmissions between
said subscriber unit and said central station from said subscriber unit on
said control channel;
switching to said at least one system predetermined communication channel
for communication with said subscriber unit and said central station in
response to said signal requesting said repeater to repeat transmissions
between said subscriber unit and said cental station; and
repeating transmissions between said subscriber unit and said central
station.
8. In a trunked communication system having at least one central controller
for allocating a limited number of communication channels among a
plurality of subscriber units and each subscriber unit having at least an
individual identification code, said subscribers constructed and arranged
to communicate information on any of the communication channels, a method
for a repeater having at least an individual identification code to
initiate communication between any of the plurality of subscribers and
said at least one central controller comprising the steps of:
(a) receiving in said repeater a first message from said subscriber unit
comprising at least a call request information word representing said
subscriber unit's identification code;
(b) receiving in said repeater a second message from said central
controller representing said subscriber unit's identification code and a
channel assignment;
(c) determining whether said second message from said central controller
has been received before receiving a predetermined number of said first
messages from said subscriber comprising at least said call request;
(d) transmitting a third message to said central controller representing
said subscriber's individual identification code and said repeater's
identification code, in response to receiving a predetermined number of
said first messages from said subscriber unit before receiving said second
message from said central controller; and
(e) receiving in said repeater a fourth message from said central
controller comprising at least channel grant information words each
representing a channel assignment for said subscriber to communicate with
said repeater, and a channel assignment for said repeater to communicate
with said central controller and other subscriber units.
9. In a trunked communication system having at least one central controller
for allocating a limited number of communication channels among a
plurality of subscriber units and each subscriber unit having at least an
individual identification code, said subscriber unit constructed and
arranged to communicate information on any of the communication channels,
said communication channels includes a plurality of designated channels, a
method for a repeater having at least an individual identification code to
provide communication between any of the plurality of subscriber units
requesting access to said repeater and said at least one central
controller comprising the steps of:
at said subscriber unit:
(a) transmitting a message to said repeater comprising at least a call
request information word being organized in fields, wherein a first field
represents said subscriber's individual identification code, and a second
field represents a status code when a signal ceases to be received from
said central station;
(b) scanning through said plurality of designated channels for reception of
a signal representing a handshake on one of said plurality of designated
channels;
(c) transmitting a signal representing an acknowledgement when said
handshake has been received on one of said plurality of designated
channels;
at said repeater:
(a) receiving said message from said subscriber unit comprising at least a
call request information word representing said subscriber's individual
identification code and said status code;
(b) transmitting a message to said central controller comprising at least a
call request information word representing said subscriber's individual
identification code and said repeater's identification code;
(c) receiving a message from said central controller comprising at least
channel grant information words each representing a channel assignment for
said subscriber to communicate with said repeater, and a channel
assignment for said repeater to communicate with said central controller
and other subscriber units;
(d) transmitting said signal representing said handshake to said subscriber
unit on said one of said plurality of designated channels;
(e) receiving said signal representing said acknowledgement from said
subscriber unit on said one of said plurality of designated channels.
10. The method of step 9, wherein step (c) at said repeater comprises the
step of switching to an assigned channel already designated for said
repeater. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates generally to radio communication systems, and more
particularly to a repeater for use when a subscriber unit is not in
communication with a central station as in trunked radio frequency
communication systems.
As disclosed in U.S. Pat. No. 4,723,264, to establish communication between
trunked subscriber units, a requesting subscriber unit transmits a call
request to a central station (or central controller). Upon receipt of the
request, the central station returns a channel grant code (if a channel is
available), which instructs the requesting subscriber unit to move to a
specified communication channel as a transmitting unit, while causing all
called subscriber units to move to the same communication channel as
receiving units.
Generally, trunked communication channels comprise a pair of frequencies.
An inbound frequency carries information from the subscriber units to the
central station, while the outbound frequency carries information from the
central station to the subscriber units. Subscriber units may be portable,
mobile or fixed. A portable unit is typically understood to be a
transceiving device designed to be carried on or about the person. A
mobile is a transceiving device designed to be installed in vehicles. A
fixed station is typically a permanent or semi-permanent installation in a
building or another fixed site. As used herein, all of these transceiving
devices are collectively referred to as subscriber units.
One situation where a subscriber unit is not in communication with a
central station occurs when the subscriber unit is operating at such a
distance (or range) from the central station that the subscriber unit has
insufficient power to transmit to the central station; even though the
more powerful central station's tansmission can reach the subscriber unit.
In this area of weak signal strength, the subscriber unit is out-of-range.
Usually, the weak signal strength zone is located in a remote or rural
area, where there are very few subscribers present to utilize the system.
Therefore, it is not economically to install a conventional repeater or
another central station.
One approach is to provide more than one conventional repeater at each weak
signal strength area in a simulcast system to amplify all the channels in
the coverage area. However, simulcast overlap problems such as
intermodulation interferences may occur.
As illustrated in U.S. Pat. No. 4,677,687, one solution pertaining to
mobile units involves installing or operating a repeater between the
central station and the mobile units to selectively relay information on a
booster channel. When the mobile unit detects a weak signal, the mobile
unit automatically switches to a predetermined booster channel for
communication with the repeater, which will relay the communication to the
central station and (and vice versa). This approach requires that each of
the mobile units be capable of recognizing the necessity to switch to the
booster channel. Generally, for cost efficiency, intalling an economical
repeater is preferred over recalling and changing existing units in the
field.
Even though the central station generally has more power to tramsmit than
the subscriber unit, beyond a certain distance at a fixed power level, the
central station will have insufficient power to reach the subscriber unit,
especially if the unit roams farther out-of-range. Here, the central
station has insufficient communication range for efficient system
operation. Therefore, an inexpensive roaming coverage may be needed in
some systems as in a trunked specialized mobile radio (SMR) system.
Likewise for a system where the central station is located far away from a
building, it is desirable to extend the distance the central station can
transmit to facilitate communication coverage anywhere within the
building.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide an
inexpensive repeater without simulcast overlap problems to know when it is
needed to extend the coverage range of a central station and/or a
subscriber unit by an automatic activation or the like.
Basically, a repeater is provided for relaying communication between a
subscriber unit and central station when the repeater recognizes
transmission from the subscriber unit to the central station, but detects
a lack of response by the central station to that subscriber unit. This
aspect of the present invention will extend the coverage range of the
subscriber unit operating at such a distance as to have insufficient power
to transmit to the central station (out-of-range subscriber unit).
In another aspect of the invention, when a central station has insufficient
coverage range to transmit to the subscriber unit, a repeater is provided
for relaying communication between the subscriber unit and the central
station. When the repeater recognizes a transmission from the subscriber
unit requesting the repeater for service, the repeater asks the central
station for a channel upon which to communicate. Alternately, a
predetermined channel may be used for the relayed communication.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of a communication system utilizing a repeater in
accordance with the present invention.
FIG. 2 is an illustration of a protocol of a conventional trunking system.
FIG. 3 is a block diagram of the repeater of FIG. 1.
FIG. 4 is a flow diagram illustrating the operation of the trunking
repeater of FIG. 3.
FIG. 5 is an illustration of a protocol of the present invention for use
with the repeater of FIG. 3.
FIG. 6 is a flow diagram for use with the repeater of FIG. 3 when the
subscriber unit is operating at such a distance that it can not receive
transmissions from the central station.
FIG. 7 is an illustration of a protocol for use with the repeater of FIG. 3
when the subscriber unit is operating at such a distance that it can not
receive transmissions from the central station.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIG. 1, a communication system utilizing a repeater in
accordance with the present invention is illustrated. A central station 10
is utilized in conjunction with a plurality of subscriber units 22, 24,
and 26. The central station 10 preferably comprises a central controller
and a plurality of repeaters, which form the fixed equipment of a trunked
radio frequency communication system. Subscriber unit 22 is shown
operating at such a distance as to have sufficient power to transmit
directly with the central station 10. Ordinarily, the central station 10
has enough power to transmit to the subscriber unit 24, but the subscriber
unit 24 is shown operating at such a distance or at such a low power that
it has insufficient power to transmit back (12) to the central station 10.
Additionally, subscriber unit 26 is shown at a range further away from the
central station 10 than that of subscriber unit 24. Therefore, central
station 10 and subscriber unit 26 are shown mutually not having sufficient
power to transmit to each other. To extend the coverage range of the
central station 10, a repeater 30 is illustrated relaying communications
between the subscriber unit 26 and the central station 10.
As is known, the central station 10 receives call requests and transmits
channel grants (if a channel is available) and other control and status
codes according to a protocol illustrated in FIG. 2. To initiate a call,
the subscriber unit 22 transmits to the central station 10 at least one
Inbound Signalling Word (ISW) on the inbound control channel 200. The ISW
202 preferably contains at least the ID field of the subscriber unit 22.
After processing the call request, the central station 10 returns at least
one Outbound Signalling Word (OSW) via the outbound control channel 300.
The OSW 206 is a command for the subscriber unit 22 along with other
receiving subscriber units to move to a first communication channel (such
as a voice channel A). As the subscriber unit 22 switches to the assigned
communication channel, a high speed handshake is transmitted on channel A
from the central station 10 to be received by the subscriber unit 22 and
the receiving subscriber units on the outbound communication channel A
(500).
After receiving the highspeed handshake 212, the requesting subscriber unit
22 transmits an acknowledge code 214 to the central station 10. In
response, the central station 10 sends a sync word 226 for the receiving
and requesting subscriber units. A low speed handshake 228 follows on the
outbound communication channel A (500). The requesting subscriber unit 22
subsequently initiates a message 216, which consists of an information
signal (for example a voice signal 218) and a connect tone 220, which is
used by the central station 10 to maintain the assigned channels as long
as the connect tone is received.
At the conclusion of the highspeed handshake 212 and sync 226, the
receiving subscriber units receive the message 218 on the outbound
communication channel A (500. The message requires the receiving
subscriber units to remain on the outbound communication channel A (500)
as long as they are receiving the low speed handshake 228. It will be
appreciated that the described protocol is an example of a conventional
trunking protocol. Other variations may require more or less signalling,
or operate with or without two speed handshakes or acknowledgement, etc.
For use with the present invention, the repeater 30 is substituted for the
subscriber unit in processing information to and from the central station
10 as will be further illustrated in FIG.7. According to the invention,
the subscriber unit 24 transmits a call request on the inbound control
channel to initiate a call. This transmission is monitored by the repeater
30. If the transmission was received by the central station 10, the
central station 10 normally returns a channel grant code with the
communication channel assignment via the outbound control channel. Without
receiving a grant, the subscriber unit 24 continues to re-transmit the
call request. However, since the transmission of subscriber unit 24 is
out-of-range for its transmission to be received by the central station
10, the repeater 30 receives the retrials of ISW without receiving a
corresponding Outbound Signalling Word channel grant from the central
staion 10. After a predetermined number of ISW retries have been received
without a corresponding OSW, the repeater 30 transmits to the central
station 10 a dual Inbound Signal Word sequence. This sequence comprises
the first ISW that subscriber unit 24 has been transmitting, and a second
ISW indicating that the transmission is being relayed by the repeater 30.
Following a proper decode sequence of the dual ISW at the central station
10, the central station 10 responds with two consecutive Outbound
Signalling Words (OSWs), which instructs the units being called by the
requesting subscriber unit 24 to receive on a second communication channel
(designated as B for convenience). Additionally, the repeater 30 is
instructed to communicate with the out-of-range subscriber unit 24 on
communication channel A (which may be a voice channel), while the repeater
30 communicates with the central station 10 on communication channel B
(which may also be a voice channel). The subscriber unit 24 is instructed
to transmit on inbound channel A. Subsequently, subscriber unit 24
transmits its message (which may be a voice signal), which is repeated by
the repeater 30 and by the central station 10 for reception by the
listening subscriber units.
To enable access for more than one subscriber, the repeater may include two
full-duplex units as illustrated in FIG. 3. An antenna 42, is coupled via
a duplexer 61 to a receiver section 46 and a transmitter section 48 (for
receiving ISWs on the inbound control channel and other signals on the
inbound communication channel and for transmitting signals on the outbound
communication channel, respectively). The synthesizer 52 sets the
frequency for the receiver 46 and transmitter 48. The output of the
receiver 46 and the input of the transmitter 48 are coupled to a
controller 54, which also controls the synthesizer 52. Any well known
microprocessor or general purpose computer containing memory may
constitute the controller 54. A second controller 54' is coupled to the
first controller 54. The other half of the duplex transceiver similarly
includes an antenna 42', a duplexer 61', a synthesizer 52', a receiver 46'
(for receiving OSWs on the outbound control channel and other signals on
the outbound communication channel) and a transmitter 68' (for
transmitting ISW on the inbound control channel and other signals on the
inbound communication channel). As is known, the duplexers 61, 61' may be
replaced by antenna switches to reduce the cost of the repeater.
The operation of the repeater of FIG. 3 will be described with reference to
FIG. 4, which are flow diagrams of the steps executed by the controllers
54, 54' of the repeater 30. These steps are followed when the requesting
subscriber unit is out-of-range. Repeater 30 is normally monitoring the
control channel at step 72. Decision 74 determines whether a channel
request ISW was received from the requesting subscriber unit calling the
central station. If no ISW was detected by the receiver 46, the standby
monitoring mode of block 72 is maintained. If, however, an ISW has been
detected, the requestor's ID is stored at block 76 in a memory portion of
the controller 54. Decision 78 determines whether a channel grant code OSW
has been transmitted from the central station 10 to the subscriber unit
24. If the OSW has been received by the receiver 46', the requestor's ID
is erased from memory at block 82, and the repeater 30 returns to the
normal standby monitoring mode of block 72. If, however, an OSW directed
to the requesting subscriber unit 24 was not detected in step 78, decision
84 searches for an ISW retry by the subscriber. If no ISW retry occurs
within a predetermined time limit (block 83), the requestor's I.D. is
erased (block 82), and the repeater returns to its monitoring state, block
72. Alternately, if the ISW retry has been detected at decision block 84,
the repeater 30 looks for an OSW directed to the subscriber unit 24 at
decision block 85. If an OSW is detected the routine branches back to
block 82. If the OSW is not detected, the repeater tansmits a dual ISW
sequence informing the central station 10 of the IDs of the out-of-range
subscriber unit and the repeater, respectively, in block 86 via the
transmitter 48'. In response to the central station's grant, the repeater
receives the first OSW, at block 88, which determines its receive
frequency for receiving communication transmissions from the out-of-range
subscriber unit. At block 92 the repeater 30 receives the channel
frequency information for relaying the received information signal (which
may be a voice signal) to the central station 10. The repeater 30 (at
block 94) acting on the information, switches to the assigned frequencies
for repeating the communication transmissions of the subscriber unit 24 to
the central station 10.
Referring to FIG. 5, a signalling protocol of the repeater of FIG. 3 is
illustrated when the subscriber unit is operating at such a distance as to
have insufficient power to transmit to the central station. When the
repeater 30 recognizes a sequence of ISW retrials without an OSW grant to
the out-of-range subscriber unit 24, the repeater 30 transmits to the
central station 10 a dual ISW sequence on the inbound control channel 200.
The first ISW 202 contains at least the ID field of the out-of-range
subscriber unit 24 and the second ISW 204 contains at least the ID of the
repeater 30. After processing the call request, the central station 10
returns a dual OSW via the outbound control channel 300. The first OSW 206
is a command for the out-of-range subscriber unit 24 and that half of the
repeater directed towards the subscriber unit to move to communication
channel A. The second OSW 208 commands the other half of the duplex
transceiver within the repeater 30 along with other receiving subscriber
units in the requesting subscriber unit's group to switch to communication
channel B. Simultaneously, the central station 10 generates a high speed
handshake code 210 for the receiving subscriber units moving to the
outbound communication channel B 400 to receive the highspeed handshake
and prepare to receive an information signal. As the out-of-range
subscriber unit 24 and the repeater 30 switch to their respective
communication channels, the high speed handshake is routed in the repeater
30 (from the receiver 46' set on channel B to transmitter 48 set for
channel A) to be received by the subscriber unit 24 on the outbound
communication channel A (500).
After receiving the highspeed handshake 212, the requesting subscriber unit
24 transmits an acknowledge code 214. The repeater 30 immediately routes
the high speed acknowledge signal 222 on inbound communication channel B
(700) (from receiver 46 to transmitter 48') for transmission to the
central station 10. In response, the central station sends the sync work
226 for the receiving subscriber units followed by the low-speed handshake
228 on the outbound communication channel B(400). Subsequently, the
requesting subscriber unit 24 initiates its message 216, which consists of
an information signal (for example a voice signal 218) and a connect tone
220, which is retransmitted by repeater 30 on inbound communication
channel B (700) to the central station 10 to maintain the assigned
channels 400, 500, 600 and 700 as long as the connect tone is received
even if the information signal 216 might cease.
At the conclusion of the acknowledge signal 222 and the highspeed handskake
210 the receiving subscriber units receive the message 224 (same message
as in 216) on the outbound communication channel B (700). The message
includes the repeated information 230 and the low-speed handshake 228,
which requires the receiving subscriber units to remain on the outbound
communication channel B (400) while they are receiving the low-speed
handshake 228.
If the central station has insufficient communication range for efficient
system operation such that it cannot directly transmit to the subscriber
unit 26, the repeater of FIG. 3 follows the steps for the controllers
54,54' in the flow diagram of FIG. 6. When the subscriber unit 26 stops
receiving from the central station 10, it transmits a requesting service
ISW to the repeater 30 to relay its transmissions and receptions. Repeater
30 is normally in the stand-by mode of block 72, monitoring the control
channel. Decision 745 determines whether a repeater service request ISW
was received from the subscriber unit 26. If no service request ISW was
detected by the receiver 46 the standby monitoring mode of block 72 is
maintained. If, however, a service request ISW has been detected, the
requestor's ID is stored at block 76 in a memory portion of the controller
54. Subsequently, the repeater transmits via the transmitter 48', a dual
ISW sequence informing the central station 10 of the IDs of the subscriber
unit and of the repeater, respectively, in block 86. After the central
station processes the information, the repeater receives the first OSW
from the central station, at block 88, which determines the repeater's
receive frequency for receiving communication transmissions from the
subscriber unit 26. At block 92 the repeater 30 receives the channel
frequency information for transmitting the received information signal to
the central station 10. Alternately, if a specific channel has been
predetermined for use by the repeater 30, steps 86, 88, and 92 are
bypassed. Step 94 follows to establish communication with the subscriber
unit 26 and the central station 30 on that predetermined channel.
FIG. 7 is an illustration of a protocol for use with the repeater of FIG. 3
when the central station needs range extension since it has insufficient
communication range for efficient system operation. Once the subscriber
unit 26 stops decoding the outbound control channel, it sends a dual ISW
302 on the last inbound control channel C (800) to advise the pre-assigned
repeater that the subscriber unit 26 cannot receive from the out-of-range
central station. In response, the repeater 30 asks the central station 10
for a channel assignment 304 for itself and the subscriber unit on inbound
control channel C (900) as in FIG. 7. After receiving and processing the
request 304, the central station 10 transmits a channel E assignment 306
for the subscriber unit and the half of the repeater 30 communicating with
the subscriber unit and the channel D assignment 308 for the other half of
the repeater 30 and the rest of the subscribers on outbound control
channel C (1000). Once there is a call for the out-of-range unit then,
repeater 30 immediately routes the High Speed Handshake (HSH) 310 on the
outbound control channel D (1100) from the receiver 46' to the transmitter
48 for transmission on the outbound communication channel E (1200) as HSH
312. Alternately, the repeater 30 may have a predetermined channel
assigned for its use and will not need to follow the channel requesting
protocol. However, regardless of how the channel is assigned, the
subscriber unit 26 scans through a list of possible channels for wide area
coverage where channel E is included. Once the subscriber unit decodes the
HSH 312 from the repeater, the subscriber unit acknowledges and operates
on the correct channel during the remainder of the conversation.
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Description |
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