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Claims  |
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I claim:
1. An interactive data broadcast network configuration having a network hub
switching center for routing communications to and from a plurality of
subscriber units comprising:
subscriber units dispersed at various locations within a base station
geographic area,
local base station repeater cell means for communicating with subscriber
units within a local base station geographic area associated with said
local base station repeater cell means by way of first data signals of
variable lengths synchronously related to a base station broadcast signal
and timed for multiplexed message transmission, said first data signals
broadcast on a first carrier frequency, said local base station repeater
cell means further comprising,
base station data processing and transmission means for transmitting to a
set of said subscriber units contained within said local base station
geographic area associated with said local base station repeater cell
means, and
a receiver for receiving from a subset of said set of subscriber units
second data messages of variable lengths broadcast on a second carrier
frequency, said second data messages multiplexed and synchronously related
to said first data signals of variable lengths to provide point-to-point
communication between said local base station repeater cell means and said
subset of said subscriber units,
store and forward repeater means for receiving said first data signals of
variable lengths transmitted by said local base station repeater cell on
said first carrier frequency and forwarding said first data signals of
variable lengths to said subscriber units on a third carrier frequency,
and
reception means for receiving and processing said second data signals
broadcast at a low power on said second carrier frequency from said
subscriber units, said reception means further comprising a local remote
receiver disposed within one of a plurality of cell subdivision sites
partitioned from said local base station geographic area associated with
said local base station repeater cell means, said plurality of cell
subdivision sites dispersed over said local base station geographic area,
each of said local remote receivers adapted for receiving said low power
second data signals from said subscriber units within range of said local
remote receiver and forwarding said second data signals to said local base
station repeater cell means.
2. The interactive data broadcast network configuration of claim 1 wherein
said store and forward repeater means further includes:
receiver means for receiving said first data signals transmitted by said
local base station repeater cell means on said first carrier frequency,
memory means coupled to said receiver means for storing said first data
signals received by said receiver means,
transmitter means coupled to said memory means for transmitting said first
data signals stored in said memory means to said subscriber units on said
third carrier frequency,
controller means coupled to said memory means for controlling the transfer
of said first data signals from said memory means to said transmitter
means, and
power supply means for providing power to said store and forward repeater
means.
3. The interactive data broadcast network configuration of claim 1 wherein
said first carrier frequency is approximately 218-219 MHz.
4. The interactive data broadcast network configuration of claim 1 wherein
said second carrier frequency is approximately 218-219 MHz.
5. The interactive data broadcast network configuration of claim 1 wherein
said first carrier frequency is the same as said third carrier frequency.
6. The interactive data broadcast network configuration of claim 5 wherein
the intensity of said first data signals transmitted by said store and
forward repeater on said third carrier frequency is greater than the
intensity of said first data signals when said first data signals are
received by said store and forward repeater on said first carrier
frequency.
7. The interactive data broadcast network configuration of claim 6 wherein
said first and third carrier frequencies are approximately 218-219 MHz.
8. The interactive data broadcast network configuration of claim 1 wherein
said memory means is further comprised of a shift register.
9. The interactive data broadcast network configuration of claim 1 wherein
said base station repeater cell means transmits said first data signals in
packets.
10. The interactive data broadcast network configuration of claim 9 wherein
said store and forward repeater stores at least one of said packets of
data and retransmits said at least one of said packets of data on said
third carrier frequency to said subscriber units.
11. The interactive data broadcast network configuration of claim 10
wherein said retransmission of said at least one of said packets of data
by said store and forward repeater is synchronized with the transmission
of packets of data by said local base station repeater cell and with said
base station broadcast signal.
12. An interactive data broadcast network system having a network hub
switching center, said interactive data broadcast network system further
comprising:
at least one subscriber unit receiving and transmitting data during
operation of said interactive data broadcast network system,
a local base station repeater cell including a transmitter and a receiver
for communicating with said at least one subscriber unit during operation
of said interactive data broadcast network system,
a store and forward repeater communicatively coupled to said local base
station repeater cell so as to receive data from said local base station
and forward said data to said at least one subscriber unit, said store and
forward repeater further comprising:
a receiver receiving data from said local base station,
a memory coupled to said receiver to store said data received from said
base station by said receiver,
a transmitter coupled to said memory to transmit said data stored in said
memory,
a controller coupled to said memory to control a transfer of data from said
memory to said transmitter, and
a power supply that provides power to components of said store and forward
repeater, and
a local remote receiver communicatively coupled to said at least one
subscriber unit and said local base station repeater cell to receive data
transmitted by said at least one subscriber unit and to forward said data
transmitted by said at least one subscriber unit to said local base
station.
13. The interactive data broadcast network system of claim 12 wherein said
local base station repeater cell and said store and forward repeater are
communicatively coupled via an rf link.
14. The interactive data broadcast network system of claim 13 wherein said
rf link is at approximately 218-219 MHz.
15. The interactive data broadcast network system of claim 12 wherein said
store and forward repeater and said subscriber unit are communicatively
coupled via an rf link.
16. The interactive data broadcast network system of claim 15 wherein said
rf link is at approximately 218-219 MHz.
17. The interactive data broadcast network system of claim 12 wherein said
subscriber unit and said local remote receiver are communicatively coupled
via an rf link.
18. The interactive data broadcast network system of claim 17 wherein said
rf link is at approximately 218-219 MHz.
19. The interactive data broadcast network system of claim 12 wherein said
memory of said store and forward repeater is a shift register.
20. A method for communicating in a two-way interactive data broadcast
network having a network hub switching center comprising the steps of:
transmitting first data signals of variable lengths synchronously related
to a base station broadcast signal and timed for multiplexed message
transmission from local base station repeater cell means on a first
carrier frequency,
receiving at a receiver of a store and forward repeater said first data
signals of variable lengths transmitted by said local base station
repeater cell on said first carrier frequency,
transmitting said first data signals of variable lengths from a transmitter
of said store and forward repeater to local subscriber units on a second
carrier frequency,
receiving at a respective receiver of said local subscriber units said
first data signals of variable lengths transmitted by said store and
forward repeater on said second carrier frequency,
transmitting second data messages of variable lengths synchronously related
to said base station broadcast signal and timed for multiplexed message
transmission from a transmitter of at least one of said local subscriber
units to a local remote receiver on a third carrier frequency,
transmitting said second data messages of variable lengths from said local
remote receiver to said local base station repeater cell means such that
point-to-point communication between said local base station repeater cell
means and said local subscriber units is achieved.
21. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting first data signals from local
base station repeater cell means on a first carrier frequency further
includes transmitting said first data signals on a first carrier frequency
of approximately 218-219 MHz.
22. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting first data signals from a store
and forward repeater on a second carrier frequency further includes
transmitting said first data signals on a second carrier frequency of
approximately 218-219 MHz.
23. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting second data signals from at
least one of said local subscriber units to a local remote receiver on a
third carrier frequency further includes transmitting said second data
signals on a third carrier frequency of approximately 218-219 MHz.
24. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting first data signals from a store
and forward repeater to local subscriber units on a second carrier
frequency further includes transmitting said first data signals on a
second carrier frequency which is the same as said first carrier
frequency.
25. The two-way interactive data broadcast network communication method of
claim 24 wherein the step of transmitting said first data signals on a
second carrier frequency which is the same as said first carrier frequency
further includes transmitting said first data signals from said store and
forward repeater at an intensity which is greater than the intensity of
said first data signals when said first data signals are received at said
store and forward repeater.
26. The two-way interactive data broadcast network communication method of
claim 24 wherein the step of transmitting said first data signals on a
second carrier frequency which is the same as said first carrier frequency
further includes transmitting said first data signals on a carrier
frequency of approximately 218-219 MHz.
27. The two-way interactive data broadcast network communication method of
claim 24 wherein the step of receiving at a receiver of a store and
forward repeater said first data signals further includes the steps of:
storing said first data signals received by said receiver in memory means
of said store and forward repeater, and
transferring said first data signals from said memory means to a
transmitter of said store and forward repeater.
28. The two-way interactive data broadcast network communication method of
claim 27 wherein the step of storing said first data signals in memory
means of said store and forward repeater further includes storing said
first data signals in a shift register.
29. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting first data signals from local
base station repeater cell means on a first carrier frequency further
includes transmitting said first data signals in packets.
30. The two-way interactive data broadcast network communication method of
claim 20 wherein the step of transmitting first data signals from a store
and forward repeater to local subscriber units on a second carrier
frequency further includes transmitting said first data signals in
packets.
31. The two-way interactive data broadcast network communication method of
claim 30 wherein the step of transmitting first data signals in packets
from a store and forward repeater to local subscriber units on a second
carrier frequency further includes synchronizing the transmission of said
packets with said local base station repeater cell means and said base
station broadcast signal. |
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Claims |
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Description |
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TECHNICAL FIELD
This invention relates to an interactive two-way data service network, and
more particularly, to communication within an interactive two-way
broadcast data service network.
BACKGROUND ART
Communication within an interactive two-way broadcast data service network
is described in detail in U.S. Pat. No. 5,388,101, by G. Dinkins, entitled
"Interactive Nationwide Data Service Communication System For Stationary
And Mobile Battery Operated Subscriber Units." In such a system, a local
base station repeater cell transmits digital data to individual low-cost,
portable, battery-operated, milliwatt transmitter, subscriber units within
a local base station designated area. A plurality of receive only
stations, remote receivers, are distributed throughout the local base
station designated area and are connected by wire, cable, microwave link,
or radio to the local base station repeater cell. The remote receivers are
referred to as receive only stations because they receive signals from the
subscriber units but do not transmit signals to the subscriber units. The
remote receivers process and relay transmitted digital data received from
the individual subscriber units. Thus, the local base station repeater
cell transmits data directly to the individual subscriber units. The
milliwatt transmitter individual subscriber units, however, do not
transmit data directly back to the local base station repeater cell.
Instead, the individual subscriber units transmit to a remote receiver
which then relays the data to the local base station repeator cell. The
use of remote receivers allows the individual subscriber units to transmit
data signals using power in the milliwatt range.
Unfortunately, under certain conditions, individual subscriber units are
unable to receive transmissions from the local base station repeater cell.
For example, a user may purchase a subscriber unit and place the
subscriber unit in, for example, a basement or other physical location
which prevents the subscriber unit from receiving transmissions from the
local base station repeater cell. Likewise, the subscriber unit might be
placed in a location such as, for example, a building with concrete walls
which substantially weaken the intensity of the rf signals received by the
subscriber unit.
In an attempt to alleviate reception problems, local base station repeater
cells have been situated with overlapping coverage to produce strong
signals throughout a given area. However, such placement of local base
station repeater cells is extremely costly due to the number of local base
station repeater cells required, and such "crowded" placement of the local
base station repeater cells is not always practical. In a further attempt
to deal with ineffective communication between the local base station
repeater cell and the subscriber unit, the location of the user is
determined at the time of sale of the subscriber unit to the user.
However, even if the user's location is within an area with strong local
base station repeater cell coverage, the subscriber unit might still be
placed in a physical location which weakens rf signals or completely
prevents the subscriber unit from receiving rf signals from the local base
station repeater cell.
Thus, the need has arisen for a system to provide for effective
transmission of data signals from a local base station repeater cell to
subscriber units in areas where such communication has previously been
impaired, which provides for the reception of strong rf signals at the
subscriber units, which does not require the addition of numerous costly
local station repeater cells, which is not dependent on the physical
location of the subscriber unit, and which does not significantly increase
the cost of communication within the interactive two-way broadcast data
service network.
DISCLOSURE OF THE INVENTION
It is therefore an object of the present invention to provide for effective
transmission of data signals from a local base station repeater cell to
subscriber units in areas where such communication has previously been
impaired, which provides for the reception of strong rf signals at the
subscriber units, which does not require the addition of numerous costly
local station repeater cells, which is not dependent on the physical
location of the subscriber unit, and which does not significantly increase
the cost of communication within the interactive two-way broadcast data
service network. The above object has been achieved using a store and
forward repeater which is used to relay data signals from a local base
station repeater cell to local subscriber units. In one embodiment, the
store and forward repeater receives rf transmissions of data signals from
the local base station repeater cell on a first carrier frequency, and
places the data signals in memory. The store and forward repeater then
retransmits the data signals over a second carrier frequency to the
subscriber units. In the present embodiment, the intensity of the data
signals retransmitted by the store and forward repeater is greater than
the intensity of the data signals received by the store and forward
repeater. In so doing, the store and forward repeater boosts the strength
of the data signals received by the subscriber units. Responses from the
subscriber unit are then transmitted over an rf link from the subscriber
unit to a local remote receiver. The local remote receiver then transmits
the responses over, for example, a hard wire link to the local base
station repeater cell. In so doing, two-way communication in an
interactive data broadcast network are achieved even in conditions which
have previously prevented such communication.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and form a part of
this specification, illustrate embodiments of the invention and, together
with the description, serve to explain the principles of the invention:
FIG. 1 shows a Prior Art interactive broadcast system wherein a local base
station repeater cell transmits data directly to a subscriber unit.
FIG. 2 shows an interactive broadcast system configuration wherein a store
and forward repeater relays data signals from a local base station
repeater cell to a subscriber unit in accordance with the present
invention.
FIG. 3 is a diagram of the timing relationship of data packets transmitted
by a local base station repeater cell and later retransmitted by a store
and forward repeater in accordance with the present invention.
BEST MODE FOR CARRYING OUT THE INVENTION
Reference will now be made in detail to the preferred embodiments of the
invention, examples of which are illustrated in the accompanying drawings.
While the invention will be described in conjunction with the preferred
embodiments, it will be understood that they are not intended to limit the
invention to these embodiments. On the contrary, the invention is intended
to cover alternatives, modifications and equivalents, which may be
included within the spirit and scope of the invention as defined by the
appended claims.
With reference now to Prior Art FIG. 1, an interactive broadcast network as
set forth in U.S. Pat. No. 5,388,101, by G. Dinkins, entitled "Interactive
Nationwide Data Service Communication System For Stationary And Mobile
Battery Operated Subscriber Units" is schematically shown. As shown in
Prior Art FIG. 1, a local base station repeater cell 10 communicates with
a subscriber unit 12 over an rf link 14 of, for example 218-219 MHz.
Subscriber unit 12 transmits data back to local base station repeator cell
10 via a remote receiver 16. That is, subscriber unit 12 transmits
messages directly to remote receiver 16 over an rf link 18. Remote
receiver 16 then transfers the messages received from subscriber unit 12
to local base station repeater cell 10 over, for example, hard wire link
20. In the present embodiment, link 18 is an rf link having a frequency in
the range of approximately 218-219 MHz. Although rf link 18 has a
frequency of approximately 218-219 MHz in the present embodiment, the
present invention is also well suited to having an rf link 18 of other
frequencies.
With reference still to Prior Art FIG. 1, under certain conditions,
subscriber unit 12 is unable to receive transmissions via rf link 14 from
local base station repeater cell 10. For example, subscriber unit 10 may
be positioned, for example, in a basement or other physical location which
weakens rf signals or completely prevents subscriber unit 12 from
receiving transmissions from local base station repeater cell 10 over rf
link 14.
With reference next to FIG. 2, a communication system including a store and
forward repeater 22 for relaying data signals between a local base station
repeater cell 10 and a subscriber unit 12 is shown. As shown in FIG. 2,
store and forward repeater 22 includes a receiver 24, memory 26,
controller 28, transmitter 30, and power supply 32. In the present
embodiment, local base station repeater cell 10 broadcasts data signals on
an rf carrier frequency. The rf link between local base station repeater
cell 10 and store and forward repeater 22 is shown as link 11. The data
signals are received by receiver 24 of store and forward repeater 22.
Receiver 24 is tuned to the rf carrier frequency of local base station
repeater cell 10. In the present embodiment, receiver 24 is tuned to
receive rf transmissions in the range of approximately 218-219 MHz.
Although receiver 24 is tuned to approximately 218-219 MHz in the present
embodiment, the present invention is also well suited to having receiver
24 tuned to other frequencies matching the transmission frequency of local
base station repeater cell 10.
Store and forward repeater 22 stores the data signals in memory 26. In the
present embodiment, memory 26 is a shift register. Although a shift
register is used in the present embodiment, the present invention is also
well suited to the use of numerous other types of memory well known in the
art. The data signals are then transferred from memory 26 to transmitter
30. Controller 28 controls the transfer of the data signals from memory 26
to transmitter 30. Transmitter 30 then transmits the data signals to
subscriber unit 12 using an rf carrier frequency. The rf link between
store and forward repeater 22 and subscriber unit 12 is shown as link 23.
Power is supplied to store and forward repeater 22 by power supply 32.
Subscriber unit 12 sends response data signals over rf link 18 to local
remote receiver 16. Local remote receiver 16 sends the response data
signals over, for example, hard wire link 20 back to local base station
repeater cell 10. Thus, the present invention provides for two-way
communication between a local base station repeater cell and a subscriber
unit.
In the present embodiment, transmitter 30 of store and forward repeater 22
transmits the data signals to subscriber unit 12 on an rf carrier
frequency which is the same as the carrier frequency at which local base
station repeater cell 10 transmits. However, transmitter 30 transmits the
data signals therefrom at an intensity which is much greater than the
intensity of the data signals when they are received at receiver 24. In so
doing, store and forward repeater 22 boosts the intensity of the data
signals at or near subscriber unit 12 to a usable level. Therefore, the
present invention enables rf communication between a local base station
repeater cell 10 and a subscriber unit 12 even in locations and conditions
where such communication has not previously been possible. As an example,
in the present embodiment, store and forward repeater 22 is placed, for
example, on the roof of a building or apartment containing subscriber
units therein and where the building or apartment is formed of reinforced
concrete or cement. Although a building or apartment formed of such
material would normally weaken or completely prevent reception by the
subscriber unit of rf signals transmitted from a local base station
repeater cell, the store and forward repeater of the present invention
sufficiently boosts the intensity of the data signals to a level which
allows subscriber unit 12 to receive rf transmissions of the data signals.
Although store and forward repeater 22 is placed on the roof of a building
or apartment in the present embodiment, the present invention is also well
suited to having store and forward repeaters 22 placed in other locations
such as, for example, in a basement of a building, on each floor of a
high-rise complex, in sports arenas, in terrain depressions, or in various
locations throughout a residential subdivision etc.
In the present embodiment, the receiver of subscriber unit 12 is tuned to
receive data signals broadcast from store and forward repeater 22 on an rf
carrier in the range of approximately 218-219 MHz. Thus, in the present
embodiment, the frequency of the rf carrier used to transmit data signals
from local base station repeater cell 10 to store and forward repeater 22
is the same as the frequency of the rf carrier used to transmit data
signals from store and forward repeater 22 to subscriber unit 12. However,
in order for the same carrier frequency to be used in link 11 and link 23,
any data signals broadcast from local base station repeater cell 10 must
be extremely weak, for example less than 95 dBm, at subscriber unit 12. If
data signals broadcast from local base station repeater cell 10 are not
extremely weak, subscriber unit 12 can receive data signals from both
local base station repeater cell 10 and store and forward repeater 22.
Overlapping data signals can result in cancellation problems and prevent
accurate communication.
In another embodiment of the present invention, in instances where data
signals broadcast from local base station repeater cell 10 are not
extremely weak at each of the respective receiving subscriber units, the
frequency of the rf carrier used to transmit data signals from local base
station repeater cell 10 to store and forward repeater 22 is different
than the frequency of the rf carrier used to transmit data signals from
store and forward repeater 22 to subscriber unit 12. That is, link 11 has
a different carrier frequency than link 23. In such an embodiment,
subscriber unit 12 is tuned to the frequency of the of the rf carrier
transmitted from store and forward repeater 22. Such an embodiment is used
for example in conditions where some of the subscriber units are able to
receive strong data signals from a local base station repeater cell and
other subscriber units are not able to receive strong data signals from
the same local base station repeater cell.
With reference still to FIG. 2, in yet another embodiment of the present
invention local base station repeater cell 10 transmits data signals in
packets. Store and forward repeater 22 receives the data signal packet and
stores one data signal packet in memory 26. Controller 28 then transfers
the data signal packet to transmitter 30 for transmission at a later time.
With reference next to FIG. 3, a diagram showing the timing relationship
between rf data signal packets transmitted from the local base station
repeater cell and the same rf data signal packets transmitted at a later
time by the store and forward repeater. As shown in FIG. 3, in the present
embodiment, the local base station repeater cell transmits a data signal
packet for a first period of time 40 and then a second period of time 42
is allotted for the subscriber unit to transmit response data signals.
However, the store and forward repeater receives the data signal packet
transmitted by the local base station repeater cell, places the data
signal packet in memory, and retransmits the data signal packet during a
third period of time 43 while leaving a fourth period of time 44 for the
subscriber unit to transmit a response data signal to the local remote
receiver.
As shown in FIG. 3, in the present embodiment, the store and forward
repeater begins transmitting the data signal packet of RF Frame 1 when the
local base station repeater cell begins transmitting the data signal
packet of RF Frame 2. Likewise, the time allotted for the subscriber unit
response period of RF Frame 1 ends at the same time the subscriber unit
response period of RF Frame 2 ends for the local base station repeater
cell. That is, the transmission and response periods of the RF Frames of
the local base station repeater cell are synchronized with the
transmission and response periods of the RF Frames of the store and
forward repeater. In the present invention, by synchronizing the
transmissions of the RF Frames, all transmissions to and from the
subscriber units remain synchronously related to a base station broadcast
signal and timed for multiplexed message transmission with the local base
station repeater cell. Although the repeater is delayed by one frame in
the present embodiment, the present invention is also well suited to
having the repeater delayed by any number of frames.
As shown in FIG. 3, in the present embodiment, transmissions from the store
and forward repeater are delayed by one RF Frame. Therefore, when the
local base station repeater cell is beginning to transmit RF Frame N, the
store and forward repeater is beginning to transmit RF Frame N-1. Although
a delay of one RF Frame is used in the present embodiment, the present
invention is also well suited to having numerous other periods of delay.
Thus, the present invention provides an interactive data broadcast network
which provides for effective transmission of data signals from a local
base station repeater cell to subscriber units in areas where such
communication has previously been impaired, provides for the reception of
strong rf signals at the subscriber units, does not require the addition
of numerous costly local station repeater cells, is not dependent on the
physical location of the subscriber unit, and does not significantly
increase the cost of communication within the interactive two-way
broadcast data service network.
The foregoing descriptions of specific embodiments of the present invention
have been presented for purposes of illustration and description. They are
not intended to be exhaustive or to limit the invention to the precise
forms disclosed, and obviously many modifications and variations are
possible in light of the above teaching. The embodiments were chosen and
described in order to best explain the principles of the invention and its
practical application, to thereby enable others skilled in the art to best
utilize the invention and various embodiments with various modifications
as are suited to the particular us contemplated. It is intended that the
scope of the invention be defined by the claims appended hereto and their
equivalents.
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Description |
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