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I claim:
1. A communications system for communicating a data message at a
pre-selected time via a radio frequency (RF) channel to a subscriber radio
operable on the RF channel and located anywhere in a geographical area,
said communications system comprising:
a plurality of communications links;
a network controller including clock means and a control station radio
operable on the RF channel, said network controller coupled to the clock
means for generating periodically a set-clock message and for generating a
data message and a pre-selected time of transmission therefor, said
network controller coupled to each of the communications links for
applying the data message and the pre-selected time of transmission
thereto, and said network controller coupled to the control station radio
for transmitting the set-clock message on the RF channel;
a plurality of base station radios each operable on the RF channel for
covering a portion of the geographical area; and
a plurality of base station controllers each including clock means and
coupled to a corresponding one of the communications links for receiving
the data message and the pre-selected time of transmission, each base
station controller coupled to its clock means and a corresponding one of
the base station radios for receiving the set-clock message from the RF
channel and resetting its clock means in response to the set-clock
message, and each of said base station controllers coupled to its clock
means and its corresponding one of the base station radios for
transmitting the data message on the RF channel at the pre-selected time.
2. The communications system according to claim 1, wherein each of said
communications links includes a first modem and a second modem
intercoupled by a communications medium, said network controller coupled
to each of said first modems, and said base station controllers each
coupled to a corresponding one of said second modems.
3. A communications system for communicating a data message having a time
of transmission appended thereto via a radio frequency (RF) channel to a
subscriber radio operable on the RF channel and located anywhere in a
geographical area, said communications system comprising:
a plurality of base station radios each operable on the RF channel for
covering a portion of the geographical area;
a plurality of base station controllers each including clock means, each
base station controller coupled to its clock means and a corresponding one
of the base station radios for receiving a set-clock message from the RF
channel, each of said base station controllers resetting its clock means
in response to the set-clock message, and each of said base station
controllers coupled to its clock means and its corresponding one of the
base station radios for transmitting the data message on the RF channel at
the time of transmission appended thereto;
a network controller including clock means and a control station radio
operable on the RF channel, said network controller coupled to the clock
means for generating periodically the set-clock message and generating the
data messsage and appending thereto a time of transmission, and said
network controller coupled to the control station radio for transmitting
the set-clock message on the RF channel; and
a plurality of communications links each coupling a corresponding base
station controller to the network controller.
4. The communications system according to claim 3, wherein each of said
communications links includes a first modem and a second modem
intercoupled by a communications medium, said network controller coupled
to each of said first modems, and said base station controllers each
coupled to a corresponding one of said second modems.
5. A simulcast communications system for simultaneously communicating from
multiple sites a data message having a time of transmission appended
thereto via a radio frequency (RF) channel to a subscriber radio operable
on the RF channel and located anywhere in a geographical area, said
communications system comprising:
a plurality of base station radios each located at a different site in the
geographical area and operable on the RF channel for covering a portion of
the geographical area;
a plurality of base station controllers each including clock means, each
base station controller coupled to its clock means and a corresponding one
of the base station radios for receiving a set-clock message from the RF
channel, each of said base station controllers resetting its clock means
in response to the set-clock message, and each of said base station
controllers coupled to its clock means and its corresponding one of the
base station radios for transmitting the data message on the RF channel at
the time of transmission appended thereto;
a network controller including clock means and a control station radio
operable on the RF channel, said network controller coupled to the clock
means for generating periodically the set-clock message and generating the
data message and appending thereto a time of transmission, and said
network controller coupled to the control station radio for transmitting
the set-clock message on the RF channel; and
a plurality of communications links each coupling a corresponding base
station controller to the network controller.
6. The simulcast communications system according to claim 5, wherein each
of said communications links includes a first modem and a second modem
intercoupled by a communications medium, said network controller coupled
to each of said first modems, and said base station controllers each
coupled to a corresponding one of said second modems.
7. A communications system for communicating a data message having a time
of transmission appended thereto via a radio frequency (RF) channel to a
subscriber radio operable on the RF channel and located anywhere in a
geographical area, said communications system comprising:
a plurality of base station radios each operable on the RF channel for
covering a portion of the geographical area;
a plurality of base station controllers each including clock means, each
base station controller coupled to its clock means and a corresponding one
of the base station radios for receiving a set-clock message from the RF
channel, each of said base station controllers resetting its clock means
in response to the set-clock message, and each of said base station
controllers coupled to its clock means and its corresponding one of the
base station radios for transmitting the data message on the RF channel at
the time of transmission appended thereto;
a network controller including clock means and a control station radio
operable on the RF channel, said network controller coupled to the clock
means for generating periodically the set-clock message and generating the
data message and appending thereto a time of transmission, and said
network controller coupled to the control station radio for transmitting
the set-clock message on the RF channel; and
a plurality of data links each coupling a corresponding base station
controller to the network controller.
8. The communications system according to claim 7, wherein each of said
data links includes a first modem and a second modem intercoupled by a
communications medium, said network controller coupled to each of said
first modems, and said base station controllers each coupled to a
corresponding one of said second modems. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention is generally related to simulcast communications
systems and more particularly to an improved simulcast data communications
systems.
In the prior art, simulcast systems have been used to substantially
simultaneously transmit from multiple base stations identical messages at
a particular radio frequency. As a result, the same message can be
transmitted simultaneously or "simulcasted" over a very large and diverse
geographical area. However, in areas covered by two or more base stations,
the message may be degraded by differences in the message path delays,
phases, modulation levels, and frequencies of the base station
transmitters. Such degradation may be reduced somewhat by accurately
controlling the base station transmitter frequencies as described in U.S.
Pat. No. 4,188,582, by randomly offsetting the base station transmitter
frequencies as described in U.S. Pat. No. 4,570,265, and/or by accurately
controlling the message delay from the controller to each base station as
described in U.S. Pat. No. 4,255,814. However, such prior art techniques
typically require expensive microwave links for connecting the controller
to each of the base stations and delay compensation circuitry in each of
the microwave links. Accordingly, there is a need for an improved method
and apparatus for inexpensively compensating for message delays between
the controller and the base stations in simulcast communications systems.
OBJECTS OF THE INVENTION
Accordingly, it is an object of the present invention to provide an
improved method and apparatus for inexpensively and accurately
compensating for message delays between the controller and the base
stations in simulcast communications systems.
It is another object of the present invention to provide an improved method
and apparatus for simultaneously transmitting the same message at a
pre-selected time from selected base stations in a simulcast
communications systems.
It is yet another object of the present invention to provide an improved
method and apparatus for simultaneously transmitting at a pre-selected
time the same message from selected base stations to a subscriber radio,
and utilizing the time of reception of acknowledgement messages from the
subscriber radio to determine the location of the subscriber radio in a
data communications systems.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of a simulcast data communications systems
embodying the present invention.
FIG. 2 is a block diagram of the network control processor in FIG. 1.
FIG. 3 is a block diagram of the general communications controller in FIG.
1.
FIG. 4 is a diagram illustrating selected messages utilized in the
simulcast data communications in FIG. 1.
FIG. 5 is a flow diagram executed by the network control processor in FIG.
1 for generating the time of transmission for a message to be transmitted
by the base station radios.
FIG. 6 is a flow diagram executed by the network control processor in FIG.
1 for updating the clocks and transmission delay times of each of the
general communications controllers.
FIG. 7 is a flow diagram executed by the general communications controller
in FIG. 1 for controlling the transmission of messages.
DESCRIPTION OF THE PREFERRED EMBODIMENT
In FIG. 1, there is illustrated a simulcast data communications system 100
that communicates messages between a network control processor (NCP) 102
and subscriber radios 190 by way of a radio frequency (RF) channel.
Although described in the context of a data only communications system,
both data signals and analog signals such as voice signals can be
communicated in messages over the RF channel. System 100 may provide data
communications to subscriber radios 190 located anywhere in a large
geographical area that is divided into a plurality of cells or zones, each
of which is covered by one or more base station radios 130-132. System 100
preferably communicates messages to subscriber radios 190 in the manner
described in U.S. Pat. Nos. 4,481,670, 4,517,669 and 4,519,068, all
incorporated herein by reference.
Subscriber radios 190 may be hand-held portable radios or vehicular-mounted
mobile radios, such as, for example, the radios described in U.S. Pat.
Nos. 4,354,252 and 4,636,791 and in Motorola Instruction manual no.
68P81035C35, available from Motorola C&E Parts, 1313 East Algonquin Rd.,
Schaumburg, Ill. 60196.
Base station radios 130-132 and control station radio 140 are coupled by
corresponding general communications controllers 120-122 and modems
108-111 via links 150-153, such as telephone lines or radio links, to
modems 104-107 coupled to NCP 102. Radios 130-132 and 140 each include a
transmitter and receiver which may be any suitable commercially available
equipment, such as, for example, the transmitter and receiver described in
Motorola Instruction manual no. 68P81013E65, available from Motorola C&E
Parts, 1313 East Algonquin Rd., Schaumburg, Ill. 60196.
According to an aspect of the present invention, system 100 also includes
control station radio 140 for transmitting a set-clock message 610 in FIG.
4 to the GCC 120-122 of all base station radios 130-132. Control station
radio 140 is identical to base station radios 130-132, with the exception
that, in the preferred embodiment, control station radio 140 only
transmits set-clock messages. The set-clock message 610 includes an
address/command portion 612 including the set-clock command, and a data
portion 613 including RTIME, the current time. Each GCC 120-123 is
responsive to receipt of the set-clock command for updating its clock 214
in FIG. 3, and thereafter transmitting an acknowledgement message via its
link 150-152 to NCP 102. NCP 102 may use the elapsed time between
transmission of the set-clock command by control station radio 140 and
receipt of each acknowledgement message from base stations 130-132 to
estimate the delay time therebetween.
According to a further aspect of the present invention, each data message
600 in FIG. 4 to be transmitted to subscriber radios 190 may be
substantially simultaneously transmitted or "simulcasted" at a
pre-selected time by base station radios 130-132. As shown in FIG. 4, each
data message 600 sent by NCP 102 to GCCs 120-122 includes an
address/command portion 602, a data portion 603 including XTIME, the
pre-selected time of transmission, and an optional information portion
604. Each GCC 120-122 compares the XTIME of a data message to the time
indicated on its clock 214 to determine when to transmit the data message.
If data messages 600 need not be simulcasted, NCP 102 sets XTIME equal to
zero. If XTIME is zero, each GCC 120-122 transmits the data message
immediately after any data messages currently being transmitted.
Referring to FIG. 2, there is illustrated a block diagram of NCP 102 in
FIG. 1. NCp 102 includes a microcomputer 500, RS232 interfaces 502 and
504-507, and clock 508. Microcomputer 500 has a memory with a stored
program therein for communicating with GCCs 120-123 and subscriber radios
190 (see U.S. Pat. Nos. 4,517,669 and 4,519,068). Microcomputer 500 is
coupled to RS232 interfaces 504-507 which are coupled to corresponding
modems 104-107 in FIG. 1. Microcomputer 500 is also coupled to RS232
interface 502 which may in turn be coupled by a dedicated telephone line
or other link to host computer 180 in FIG. 1. Information in messages
received from subscriber radios 190 by way of GCCs 130-132 is forwarded by
microcomputer 500 to host computer 180. Conversely, information to be sent
to subscriber radios 190 from host computer 180 is transmitted to
microcomputer 500 and incorporated into messages for transmission to
designated subscriber radios 190. The blocks of NCP 102 in FIG. 2 may be
implemented with conventional circuitry, such as, for example, the 6800 or
68000 series of microcomputers and peripheral circuitry available from
Motorola, Inc.
Microcomputer 500 in FIG. 2 is also coupled to a clock 508, which may be an
atomic-based clock or any other conventional real-time clock circuit.
Microcomputer 500 reads clock 508 and adds the read-out time of clock 508
to an offset to produce a time of transmission XTIME. The transmission
time XTIME 603 and an optional information portion 604 is appended to data
messages 600 in FIG. 4 and simulcasted by selected base station radios
130-132. The clocks 214 of GCCs 120-122 are synchronized to clock 508 by
appending the read-out time RTIME of clock 508 to set-clock message 610 in
FIG. 4 which is sent by control station radio 140 to the GCCs 120-122 of
base station radios 130-132.
Referring to FIG. 3, there is illustrated a block diagram of GCCs 120-123
in FIG. 1. Each GCC 120-123 includes a microcomputer 202, RS232 interface
204, filter 206, filter 208, limiter 210, A/D converter 212, interface
adaptor 216, and clock 214. Microcomputer 202 has a memory with a stored
program therein for communicating with NCP 102 and subscriber radios 190
(see U.S. Pat. Nos. 4,517,669 and 4,519,068). Microcomputer 202 is coupled
to RS232 interface 204 which in turn is coupled by a modem 104-107 to a
dedicated telephone line or other link to NCP 102. Messages received by
microcomputer 202 from NCP 102 may be coupled to filter 206 and thereafter
applied to the transmitter of its corresponding radio 130-132 and 140.
Messages received from subscriber radios 190 by the receiver of its
corresponding radios 130-132 and 140 are coupled to filter 208 and
thereafter to limiter 210, which converts the analog signals into binary
signals. The output of limiter 210 is applied to an input port of
microcomputer 202. Interface adaptor 216 may be used to measure the phase
of messages received from subscriber radios 190. The blocks of GCC 120-123
in FIG. 3 may be implemented with conventional circuitry, such as, for
example, the 6800 or 68000 series of microcomputers and peripheral
circuitry available from Motorola, Inc.
In addition to receiving and transmitting messages, microcomputer 202 in
FIG. 3 also takes signal strength indication (SSI) readings of the
messages received from subscriber radios 190 (see U.S. Pat. No.
4,481,670). The SSI signal from the receiver of its corresponding radio
130-132 and 140 is coupled to A/D converter 212, which may continuously
convert the analog SSI signal to a digitized SSI signal. The digitized SSI
signal from A/D converter 212 is applied to an input port of microcomputer
202. Several A/D conversions may be performed while a message is being
received. The digitized SSI signals of the several conversions are
averaged by microcomputer 202. The average SSI signal is appended to the
received message which is sent by microcomputer 202 via RS232 interface
204 to NCp 102
Microcomputer 202 in FIG. 3 is also coupled to a clock 214, which may be
any conventional settable real-time clock circuit. Microcomputer 202 reads
clock 214 to determine when to send a data message 600 in FIG. 4 that is
to be simulcasted by base station radios 130-132. Clock 214 is
synchronized to clock 508 of NCP 102 by presetting clock 214 to the value
of RTIME in the set-clock message 610 in FIG. 4 received from NCP 102.
In control station radio 140, microcomputer 202 in FIG. 3 is also coupled
to an interface adaptor 216, which may be a conventional peripheral
interface adaptor suitable for coupling parallel or serial data to or from
microcomputer 202. Interface adaptor 216 may be coupled to the frequency
synthesizer of radio 140 for receiving digital data therefrom
representative of the frequency of operation or the frequency deviation of
the transmitters of radios 130-132. Microcomputer 202 reads interface
adaptor 216 to determine the frequency or deviation of the transmitter of
a base station radio 130-132 which is transmitting a message. The
frequency and deviation measurements taken for base station radios 130-132
are sent by microcomputer 202 of GCC 123 to NCP 102 via link 153. NCP 102
may send messages to a GCC 120-122 for automatically adjusting the
frequency or deviation of the transmitter of the associated base station
radio 130-132 found to be outside of system specifications.
Referring to FIG. 5, there is illustrated a flow diagram executed by
microcomputer 500 of NCP 102 in FIG. 1 for generating the time of
transmission XTIME for a data message 600 to be simulcasted by the base
station radios 130-132. Entering at START block 702 and proceeding to
block 704, N is set to one and DMAX is set to zero. The number N
represents the number of base station radios 130-132 in system 100 and
varies from N=1 to N=NMAX.
Next, at block 706, the delay time DTIME(N) for base station radio N is
read. The delay time DTIME(N) is an array stored in NCP microcomputer 500
containing the delay time between NCP 102 and base station radio N. As
previously explained, the delay time DTIME(N) may be determined by
actually measuring the delay of each path using suitable test equipment,
or by automatically measuring at NCp 102 the delay between a set-clock
message and the acknowledgement thereof from base station radio N, or by
any other suitable conventional method of measurement. Next, at decision
block 708, a check is made to determine if DTIME(N) is greater than DMAX.
If so, YES branch is taken to block 710 where DMAX is set equal to
DTIME(N). If DTIME(N) is not greater than DMAX, NO branch is taken from
decision block 708 to block 712 where N is incremented by one. Then, at
decision block 714, a check is made to determine if N is greater than
NMAX. If not, NO branch is taken back to block 706 to read the delay time
DTIME(N) for the next base station radio 120-132.
If N is equal to NMAX, YES branch is taken from decision block 714 to block
716 where the real time clock RTIME is read. Then, at block 718, the
transmission time XTIME is set equal to DMAX plus a preselected amount of
time OFFSET allowing for processing delays. Next, at block 720, the same
data message 600 including an address/information portion 602, XTIME 603
and information portion 604 is sent to selected GCCs 120-122 for
transmission by the corresponding base station radios 30-132. Depending on
the nature of the data message 600 and the size of the system 100, data
message 600 may be simulcasted by all or a selected portion of the base
station radios 130-132. Thereafter, program control returns to other tasks
at RETURN block 722.
Referring to FIG. 7, there is illustrated a flow diagram executed by
microcomputer 202 of GCCs 120-122 in FIG. 1 for controlling the
transmission of messages. Entering at START block 302 and proceeding to
decision block 304, a check is made to determine if a set-clock message
610 has been received. If so, YES branch is taken to block 306 where clock
214 is set with the new time RTIME 613 received in the set-clock message
610, after which, an acknowledgement message is sent over the
corresponding link 150-152 to NCP 102. If a set-clock message 610 has not
been received, NO branch is taken from decision block 304 to decision
block 308 where a check is made to determine if a data message 600 has
been received. If not, NO branch is taken to RETURN block 310 to return to
other tasks.
If a data message 600 has been received, YES branch is taken from decision
block 308 to block 322 where the address/command portion 602, transmission
time XTIME 603 and information portion 604 of the data message 600 is
read. Then, at block 324, the time RTIME of clock 214 is read. Next, at
decision block 326, a check is made to determine if a RTIME is equal to
XTIME. If not, NO branch is taken back to block 324 to read clock 214
again. If RTIME is equal to XTIME (exact equality need not be required in
practicing the present invention), YES branch is taken from decision block
326 to block 328 where data message 600 is transmitted. All GCCs 120-122
receiving data message 600 will be simulcasting it at substantially the
same time. Thereafter, program control returns to other tasks at RETURN
block 330.
Additional process steps may be added to FIG. 7 between blocks 328 and 330
for determining the time of reception and phase of an acknowledgement
message from the subscriber radio 190 receiving data message 600. Clock
214 is read to provide a time of receipt when the acknowledgement messages
is received, and interface adaptor 216 may measure the phase of the
acknowledgement message. The time of receipt and phase measurements made
by each GCC 120-122 may then be sent to NCP 102. NCP may use the time of
receipt and phase measurements to determine the approximate location of
the subscriber radio 190 by conventional triangulation calculations.
Referring to FIG. 6, there is illustrated a flow diagram executed by
microcomputer 500 of NCP 102 in FIG. 1 for updating the clocks 214 and
transmission delay times DTIME of each of the GCCs 120-122. Entering at
START block 402 and proceeding to block 404, the time RTIME1 of NCP clock
508 is read. Then, at block 406, a set-clock message 610 is transmitted by
control station radio 140 to all base station radios 130-132. Next, at
decision block 408, a check is made to determine if an acknowledgement
message has been received from any of the GCCs 120-122. If not, NO branch
is taken back to decision block 416 to check to determine if the
acknowledgement time period is over. If not, NO branch is taken from
decision block 416 back to decision block 408.
If an acknowledgement message has been received from one of the GCCs
120-122, YES branch is taken from decision block 408 to block 410 where
the time RTIME2 of NCP clock 508 is read again. Then, at block 412, the
identity of the base station radio 130-132 is determined from the
acknowledgement message. Assuming base station radio N has been
identified, the delay time DTIME(N) is set equal to one-half the
difference between RTIME2 and RTIME1 at block 414 and stored in the memory
of NCP microcomputer 500. Next, at decision block 416, a check is made to
determine if the acknowledgement time period is over. If not, NO branch is
taken from decision block 416 back to decision block 408. If the
acknowledgement time period is over, YES branch is taken from decision
block 416 to RETURN block 418 to return to other tasks.
The flow diagrams in FIGS. 5, 6 and 7 provide a detailed description of the
process steps used by the microcomputers of NCP 102 and GCCs 120-122 in
FIG. 1 for simulcasting messages to subscriber radios 190. The coding of
the process steps of the flow diagrams in FIGS. 5, 6 and 7 into the
instructions of a suitable commercially available microcomputer is a mere
mechanical step for a routine skilled in the art. By way of analogy to an
electrical circuit diagram, the flow diagrams in FIGS. 5, 6 and 7 are
equivalent to a detailed schematic for an electrical circuit where
provision of the exact part values for the electrical components in the
electrical schematic corresponds to provision of microcomputer
instructions for blocks in the flow diagrams.
In summary, an improved method and apparatus has been described that
inexpensively and accurately compensate for message delays between the
controller and the base stations in simulcast communications systems.
According to another aspect of the present invention, the same message may
be simulcasted by selected base station radios at a pre-selected time. The
delay compensation and precise simulcasting aspects of the present
invention may be advantageously utilized in a variety of applications
where simulcast communications are desired. Therefore, while a particular
embodiment of the present invention has been shown and described, it
should be understood that the present invention is not limited thereto
since other embodiments may be made by those skilled in the art without
departing from the true spirit and scope thereof. It is thus contemplated
that the present invention encompasses any and all such embodiments
covered by the following claims.
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