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| United States Patent Application |
20070112705
|
| Kind Code
|
A1
|
|
Mardirossian; Aris
|
May 17, 2007
|
Balloon/airborne communication system
Abstract
A system and method for enabling an airborne communication system when a
natural disaster is detected, or when it is detected that an occurrence
of a natural disaster is imminent or likely, is provided. In certain
example embodiments, a natural disaster detector monitors, for example,
various climatic indicators to determine whether a natural disaster is
about to occur, is currently occurring, or has just occurred. An
elevation device or system with an attached communication component(s)
may elevate before, during, or after the natural disaster, depending on
the example embodiment. Once the communication component is airborne, the
communication system will create or restore a particular communication
channel. In other example embodiments, a plurality of elevation devices,
each with their own associated communication components may be elevated
to facilitate a node-like implementation.
| Inventors: |
Mardirossian; Aris; (Germantown, MD)
|
| Correspondence Name and Address:
|
NIXON & VANDERHYE, PC
901 NORTH GLEBE ROAD, 11TH FLOOR
ARLINGTON
VA
22203
US
|
| Assignee Name and Adress: |
Technology Patents, LLC
Derwood
MD
|
| Serial No.:
|
272435 |
| Series Code:
|
11
|
| Filed:
|
November 14, 2005 |
| U.S. Current Class: |
706/21; 340/825.25; 340/825.69; 706/24 |
| U.S. Class at Publication: |
706/021; 706/024; 340/825.69; 340/825.25 |
| Intern'l Class: |
G06F 15/18 20060101 G06F015/18 |
Claims
1. A method of establishing an airborne communication system in view of a
natural disaster, the method comprising: detecting a natural disaster;
elevating a communication component in response to detecting the natural
disaster; and activating said communication component so that an airborne
communication system is established.
2. The method of claim 1, wherein the natural disaster is a tropical
depression, an earthquake, a hurricane, a tornado, a tsunami, a wildfire,
and/or a terrorist attack.
3. The method of claim 1, wherein the detecting step monitors barometric
pressure, temperature, seismic activity, and/or water levels.
4. The method of claim 1, further comprising requiring verification before
elevating and/or activating the communication component.
5. The method of claim 1, wherein the activating step allows communication
via telephones, cellular telephones, and/or walkie-talkies.
6. A method of establishing an airborne communication system in view of a
disaster, the method comprising: detecting a disaster or the possibility
of a natural disaster; in response to said detecting step, elevating a
plurality of communication components; and, activating said plurality of
communication components.
7. The method of claim 6, wherein the elevating step elevates
communication components to replace communication components damaged or
which may be damaged by the disaster.
8. A system that establishes an airborne communication system, comprising:
a natural disaster detector; an elevating device for elevating
communications equipment in response to detection of a natural disaster;
and, a communication component attached to said elevating device so that
an at least partially airborne communication system can be realized upon
detection of the natural disaster.
9. The system of claim 8, wherein the natural disaster is a tropical
depression, an earthquake, a hurricane, a tornado, a tsunami, a wildfire,
and/or a terrorist attack.
10. The system of claim 8, wherein the natural disaster detector
determines the presence of a natural disaster by monitoring barometric
pressure, temperature, seismic activity, and/or water levels.
11. The system of claim 8, where a user confirms the output of the natural
disaster detector and/or activates the communication component.
12. The system of claim 8, wherein the communication component allows
communication via telephones, cellular telephones, and/or walkie-talkies.
13. The system of claim 12, wherein the communication component allows
communication over a secure and/or restricted channel.
14. The system of claim 8, wherein the elevation device is a balloon.
Description
FIELD OF THE INVENTION
[0001] Certain example embodiments of this invention relate to a system
and method for permitting an airborne communication system to be realized
when a natural disaster is detected. In certain example embodiments, a
system and/or method is provided for enabling an airborne communication
system when a natural disaster is detected by elevating at least a
central communication server. In certain other example embodiments, a
system and/or method is provided for enabling an airborne communication
system when a natural disaster is detected by elevating at least nodes in
a distributed communication infrastructure.
BACKGROUND AND SUMMARY OF EXAMPLE EMBODIMENTS OF THE INVENTION
[0002] Natural disasters--including tropical depressions, hurricanes,
tornados, and wildfires--injure and kill thousands in the United States.
Though not common in the U.S., tsunamis and earthquakes pose similar
threats elsewhere around the world. The devastating effects of natural
disasters are not limited to immediate injuries to people in the direct
path of the storms. Rather, damage to critical infrastructure, emergency
supplies, and the like hampers the effective response of rescue workers.
For example, water supplies may become contaminated as flood waters rage
out of control. Hospitals may be leveled, preventing the treatment of
otherwise routine injuries. Disease may spread. And blocked roads,
collapsed bridges, and the like prevent the effective movement of
resources from one place to another. Thus, there is a real and dire risk
that many people in disaster areas will suffer new injuries, face further
maladies, or even die while rescue workers struggle to help them.
Communication is critical in this respect.
[0003] Ordinarily, the provision of goods and services is accomplished
through a complex communication and information network. In disaster
areas, there is a heightened need for the efficient delivery of goods and
services, particularly medical supplies and food. But when disaster
strikes, damage frequently is done to the critical communication and
information infrastructure, challenging both the provision of supplies
and the coordination of relief efforts.
[0004] Traditional communication methods that include ground components
typically cannot withstand the awesome force of nature, or they are
simply rendered inoperable. For example, tornadoes can knock over
telephone poles, earthquakes can swallow cell towers, and hurricanes can
envelop satellite transmitters and/or receivers. Components used in more
resilient communication methods may be too expensive, slow and/or
difficult to implement, or prove ineffective because of their proprietary
nature.
[0005] Thus, it will be appreciated that there exists a need in the art
for a method and/or system for enabling an airborne communication system
when a natural disaster is detected and/or realized, at least to serve as
a tool for assisting responders to coordinate relief efforts.
[0006] Therefore, certain example embodiments of this invention seek to
provide low-cost, highly-flexible alternative communication systems when
natural disasters are detected. In accordance with certain example
embodiments, a method is provided for establishing an airborne
communication system. In certain example embodiments, the method
comprises detecting a natural disaster, elevating a communication
component, and activating said communication component. The natural
disaster may be, for example, a tropical depression, an earthquake, a
hurricane, a tornado, a tsunami, a wildfire, and/or a terrorist attack.
In some example embodiments, the detecting step may determine the
presence of a natural disaster by monitoring barometric pressure,
temperature, seismic activity, and/or water levels. Some example
embodiments also may include the step of requiring verification before
elevating and/or activating the communication component. Depending on the
example embodiment, the activating step may enable communication via
telephones, cellular telephones, and/or walkie-talkies.
[0007] Other example embodiments provide a method for establishing an
airborne communication system, comprising the following steps of
detecting a natural disaster, elevating a plurality of communication
components, and activating the plurality of communication components. In
some example embodiments, the elevating step elevates communication
components to replace communication components damaged by the natural
disaster.
[0008] Certain example embodiments provide a system that establishes an
airborne communication system. Such a system may comprise a natural
disaster detector, an elevating device, and a communication component
attached to the elevating device. In some example embodiments, the
natural disaster detector determines the presence of a natural disaster
by monitoring barometric pressure, temperature, seismic activity, and/or
water levels. In other example embodiments, a user confirms the output of
the natural disaster detector and/or activates the communication
component. In still other example embodiments, the communication
component enables communication via telephones, cellular telephones,
and/or walkie-talkies. Furthermore, the communication component may
enable communication over a secure and/or a restricted channel. In
certain example embodiments, the elevation device is a balloon.
[0009] In certain other example embodiments, a system of establishing an
airborne communication system is provided, which comprises a natural
disaster detector, a plurality of elevating devices, and a plurality of
communication components attached to the plurality of elevating devices.
In other embodiments, communication components are elevated to replace
communication components damaged by said natural disaster.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] These and other features and advantages will be better and more
completely understood by reference to the following detailed description
of exemplary illustrative embodiments in conjunction with the drawings,
of which:
[0011] FIG. 1 is a flowchart according to an example embodiment;
[0012] FIG. 2A is a partial schematic view of a system for enabling an
airborne communication system when a natural disaster is detected
according to an example embodiment;
[0013] FIG. 2B is a partial schematic view of a system for enabling an
airborne communication system when a natural disaster is detected
according to another example embodiment; and,
[0014] FIG. 3 is a non-limiting view of a deployed system according to an
example embodiment.
DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS OF THE INVENTION
[0015] Referring now to the drawings, FIG. 1 is a flowchart according to a
first exemplary embodiment. Step S10 detects whether a natural disaster
is occurring or has occurred. The natural disasters detected in step S10
may include, for example, tropical depressions, earthquakes, hurricanes,
tornados, tsunamis, wildfires, etc. Step S10 may monitor climatic
attributes that typify the occurrence of natural disasters, such as, for
example, sudden changes in barometric pressure, temperature increases
above certain threshold levels, seismic activity, rising water levels,
etc. It will be appreciated, however, that step S10 may detect other
natural disasters apart from or in addition to the above non-limiting
list, including those natural disasters that occur in alone, together, in
succession, etc. It also will be appreciated that step S10 may monitor
other indicators, alone or in combination, that are correlated with the
existence of natural disasters.
[0016] Above-described step S10 employs an automatic detector that
monitors climatic attributes correlated with the presence of natural
disasters in order to, for example, keep people out of harm's way.
However, other example embodiments are contemplated wherein step S10
might include a human element--e.g., the step of detecting a natural
disaster may be undertaken by a human operator. A system with a human
operator performing the detecting step may, for example, have the human
operator located locally or remotely. In some example embodiments, having
a human operator may be, for example, less expensive, more reliable, etc.
than employing complex mechanical detectors.
[0017] If a natural disaster is detected in step S10, an elevation device
will be released in step S12. In an example embodiment, a self-contained,
independent communication component will be attached to the elevation
device. In some example embodiments, in a step not shown in FIG. 1, the
system may comprise the additional step of determining when to release
the elevation device. The timing step may be used in view of the type of
natural disaster occurring. For example, during an earthquake, it may
make sense to release the elevation device as soon as seismic activity
above a certain threshold is detected to avoid damage to the elevation
device and accompanying communication component. However, releasing an
elevation device during a tornado, for example, may prove
counterproductive, as high winds may damage the elevation device itself
and/or the communication component attached thereto. Alternatively, or in
addition to the timing step, the release of the elevation device may
require human confirmation in some example embodiments. In a preferred
embodiment, the elevation device will consist of an inflatable balloon or
plurality of inflatable balloons. For example, it is well known that
weather balloons may remain aloft for long periods of time carrying
sensitive equipment through a varied range of outside conditions.
However, it will be appreciated that using a balloon or a plurality of
balloons is only one elevation device, and other suitable elevation
devices may be used in place of, or in combination with, the balloon or
plurality of balloons.
[0018] Also, it will be appreciated that step S12 may release a plurality
of elevation devices, each with an attached communication component. In
some example embodiments, it may be necessary to release a plurality of
elevation devices to cover a sufficiently broad area. In other example
embodiments, it may be necessary to release a plurality of elevation
devices to enable the specific communication system chosen. Details of
the communication system will be discussed below in combination with step
S14. Briefly, communication systems in accordance with some example
embodiments may require multiple nodes for relaying communiques across a
network of communications components. It will be appreciated that in
implementing a network of nodes, the same communication components may be
used on each elevation device, while in other example implementations,
different communication components may be necessary. The former example
implementation may constitute, in part, for example, an ad-hoc system of
communication relays. The latter example implementation may constitute,
in part, for example, a hub-and-spoke communication system.
[0019] Step S14 involves activating the communication system. The
communication system can be one or more of, for example, a cellular
system, satellite broadcast, short-wave radios, etc. The system may
operate at various frequencies, depending on, for example, the
communication system chosen, the specific needs of responders, the nature
of the disaster, etc. For example, where law enforcement needs are
especially great, the communication system may enable communication via
police frequencies. Where, for example, the National Guard or the Army
Corps of Engineers are deployed, the communication system may enable
communication via military frequencies. In some example embodiments, the
communication system may operate over open channels, while the
communication may operate over secure and/or encrypted channels in other
example embodiments. Similarly, depending on the example embodiment, the
communication system may be restricted to certain users, certain groups
of users, or open to all users.
[0020] In some example embodiments, before the system reaches the
activating step, the system may wait for a human confirmation to activate
the system. The additional step of requiring human confirmation may be
advantageous in cases where, for example, natural disasters are detected
which trigger the elevation step, but where the airborne system is not
needed. This may occur when, for example, traditional communications
devices are not damaged by the natural disaster.
[0021] In still other example embodiments, the activating step may further
comprise a verification step, wherein the operability of the airborne
communication system is checked. Additionally, the communication system
may accept a shut-down signal when, for example, the emergency period is
over, traditional communication channels are restored, relief efforts are
completed, etc.
[0022] FIG. 2A is a partial schematic view of a system for enabling an
airborne communication system when a natural disaster is detected
according to an example embodiment. Natural disaster detector 200
determines the existence of one or more than one natural disaster.
Natural disaster detector 200 may monitor climatic attributes, such as,
for example, sudden changes in barometric pressure, temperature increases
above certain threshold levels, seismic activity, rising water levels,
etc. in order to indicate, for example, tropical depressions,
earthquakes, hurricanes, tornados, tsunamis, wildfires, etc.
[0023] If a natural disaster is detected by natural disaster detector 200,
elevation device 212 will rise, carrying communication component 214 with
it. In a preferred embodiment, elevation device 212 will consist of one
or more balloons. Communication component 214 may enable, for example, a
cellular system, satellite broadcast, short-wave radios, etc., and it may
operate at various frequencies--open or restricted--depending on, for
example, the communication system chosen, the specific needs of
responders, the nature of the disaster, etc.
[0024] FIG. 2B is a partial schematic view of a system for enabling an
airborne communication system when a natural disaster is detected
according to another example embodiment. In this example embodiment, when
natural disaster detector 200 detects a natural disaster, one or more of
a plurality of elevation devices, each carrying its own communication
component, is/are released. For example, in a preferred embodiment that
utilizes a multi-node system, it may be necessary to release a plurality
of elevation devices to enable, for example, communication across a broad
geographic area via cellular communications. In this example embodiment,
different communication components may be necessary for different
elevation devices, depending on the communication system implemented. For
example, in some example embodiments, it may be necessary to have a
central parent communication component in contact with child
communication components.
[0025] FIG. 3 is a non-limiting view of a deployed system according to an
example embodiment. Considering FIG. 3 from left-to-right illustrates how
an airborne communication system in accordance with one example
embodiment may be deployed. Natural disaster 30, shown for non-limiting
illustrative purposes as a tornado, is detected by natural disaster
detector 32. When natural disaster 30 is detected, the plurality of
elevation devices 34 rise, carrying the plurality of communication
components 36 with them. After the airborne communication system is
activated, rescue worker 38 is then able to use communication device 40,
pictured for non-limiting illustrative purposes as a walkie-talkie.
[0026] In other example embodiments contemplated by the present invention,
the plurality of elevation devices 34 pictured in FIG. 3 may be shielded
and/or protected before they are deployed. Protecting and/or shielding
the elevation devices may be necessary in some example embodiments to
prevent the attached potentially-sensitive communication components from
being damaged during the occurrence of the natural disaster. Such a
shielding/protecting structure may have to be resilient enough to
withstand, for example, high winds, falling debris, water damage.
[0027] It will be appreciated that while the example embodiments described
may be used a replacement system for traditional, existing communication
channels, the airborne communication system described herein may be used
as an alternative system in place of, or in addition to, the existing
communication channels. This may be necessary when, for example,
traditional communication channels still function properly but become
overloaded by an abnormally high-density call volume. Similarly, it will
be appreciated that the airborne communication system may replace damaged
nodes in an existing communication network. Thus, certain example
embodiments may use the airborne communication system to "patch" holes in
existing networks.
[0028] Additionally, it will be appreciated that multiple communication
devices may be located on each elevation device in order to enable and/or
make available a number of different communication networks. This
function may be advantageous, for example, to create new communication
channels for rescue workers while restoring traditional channels to
everyday citizens.
[0029] Although the example embodiments herein have been described to
detect natural disasters, it will be appreciated that airborne
communication systems may be useful in other circumstances, including,
for example, emergency situations in general. One obvious emergency
situation that could have impacts similar to a natural disaster would be
a terrorist attack.
[0030] While the invention has been described in connection with what is
presently considered to be the most practical and preferred embodiment,
it is to be understood that the invention is not to be limited to the
disclosed embodiment, but on the contrary, is intended to cover various
modifications and equivalent arrangements included within the spirit and
scope of the appended claims.
* * * * *
