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| United States Patent Application |
20060173681
|
| Kind Code
|
A1
|
|
Koch; F. Elliott
; et al.
|
August 3, 2006
|
Semi-covert emergency transmitter
Abstract
A semi-covert emergency transmission device and methodology for soldiers
and other such personnel requiring pick-up or rescue is disclosed. The
device has a flashlight mode and a transmit mode. In flashlight mode, an
LED is turned on to provide an illumination source that can be used in
numerous applications. In transmit mode, the device uses the same LED to
transmit a coded message that includes information relevant to the user.
The coded message can be preprogrammed and stored in the device, or
translated in real-time. The transmit mode is further configured so as to
confirm that the intended user is the one requesting the transmission of
the coded message. The light emitted from the LED can be seen for up to a
mile or so away by friendly forces or other potential rescuers.
| Inventors: |
Koch; F. Elliott; (Moorpark, CA)
; Maloney; Patrick G.; (Arlington, VA)
; Ciemiewicz; Jon T.; (Litchfield, NH)
|
| Correspondence Name and Address:
|
MAINE & ASMUS
P. O. BOX 3445
NASHUA
NH
03061
US
|
| Assignee Name and Adress: |
BAE SYSTEMS INFORMATION AND ELECTRONIC SYSTEMS INTEGRATION INC
Nashua
NH
|
| Serial No.:
|
047935 |
| Series Code:
|
11
|
| Filed:
|
February 1, 2005 |
| U.S. Current Class: |
704/246; 704/E17.003 |
| U.S. Class at Publication: |
704/246 |
| Intern'l Class: |
G10L 17/00 20060101 G10L017/00 |
Claims
1. A semi-covert emergency transmitter device, comprising: a microphone
for receiving verbal input, and converting that verbal input to an
electrical signal; a voice recognition module adapted for verifying the
verbal input was spoken by an intended user; a processor adapted to
provide a coded message in response to the voice recognition module
verifying the verbal input was spoken by the intended user; and an light
emitting diode (LED) for transmitting the coded message provided by the
processor.
2. The device of claim 1 further comprising: an analog to digital
converter adapted to convert the electrical signal from the microphone
into its digital equivalent and to provide that digital signal to at
least one of the processor and voice recognition module.
3. The device of claim 1 further comprising: a translation module adapted
to convert the verbal input into a coded form that can be at least one of
stored in a memory of the device and transmitted by the LED.
4. The device of claim 1 wherein the processor is further adapted to
provide the coded message only in response to the verbal input being
spoken by the intended user a pre-defined number of times.
5. The device of claim 1 wherein the processor has a transmit mode and a
flashlight mode, with each mode being initiated by a user input
requesting a particular mode.
6. The device of claim 5 wherein in the flashlight mode, the processor
turns the LED on to provide an illumination source.
7. The device of claim 1 wherein the coded message is stored in a memory
accessible by the processor.
8. The device of claim 1 wherein the voice recognition module is
integrated into the processor.
9. A semi-covert emergency transmitter device, comprising: a microphone
for receiving verbal input, and converting that verbal input to an
electrical signal; a verification module adapted for verifying the verbal
input was provided by an intended user; a processor adapted to provide a
coded message in response to the verification module verifying the verbal
input was spoken by the intended user; and a light source for
transmitting the coded message provided by the processor.
10. The device of claim 9 further comprising: an analog to digital
converter adapted to convert the electrical signal from the microphone
into its digital equivalent and to provide that digital signal to at
least one of the processor and verification module.
11. The device of claim 9 further comprising: a translation module adapted
to convert the verbal input into a coded form that can be at least one of
stored in a memory of the device and transmitted by the light source.
12. The device of claim 9 wherein the processor is further adapted to
provide the coded message only in response to the verbal input being
spoken by the intended user a pre-defined number of times.
13. The device of claim 9 wherein the processor has a transmit mode and a
flashlight mode, with each mode being initiated by a user input
requesting a particular mode.
14. The device of claim 13 wherein the light source is an light emitting
diode (LED).
15. The device of claim 9 wherein the coded message is stored in a memory
accessible by the processor.
16. The device of claim 9 wherein the verification module is integrated
into the processor.
17. A method for semi-covert emergency transmission, comprising: receiving
an electrical signal representative of a verbal input; verifying the
verbal input was provided by an intended user; and in response to
verifying the verbal input was spoken by the intended user, transmitting
a coded message using a light source, thereby signaling a need for help
in a semi-covert manner relative to radio frequency transmissions.
18. The method of claim 17 further comprising: converting the verbal input
into a coded form that can be at least one of stored in a memory of the
device and transmitted by the light source.
19. The method of claim 17 wherein verifying the verbal input was provided
by an intended user includes performing voice recognition on the verbal
input.
20. The method of claim 17 wherein verifying the verbal input was provided
by an intended user includes ensuring the verbal input was spoken a
pre-defined number of times.
Description
FIELD OF THE INVENTION
[0001] The invention relates to emergency transmitters, and more
particularly, to a semi-covert emergency transmitter for soldiers and
other such personnel requiring rescue.
BACKGROUND OF THE INVENTION
[0002] In general, an emergency transmitter is a device that can be used
by a person who, for what ever reason, requires assistance or rescue. The
transmitter can be as simple as a conventional flash light or a more
complex radio frequency (RF) transmitter. In any such cases, the
transmitter can be used to signal the location of the person needing
assistance.
[0003] The person could be, for instance, alone in their house or taking a
walk, when they suddenly feel ill (e.g., from an ensuing heart attack or
some other threatening condition). In such a case, the person could
activate their personal emergency transmitter, which typically transmits
or causes to be transmitted an RF signal that can be detected by a remote
service organization that will then dispatch the appropriate personnel
(e.g., such as medical personnel) to aid the ailing person.
[0004] The information transmitted by the emergency transmitter typically
includes the location of the person at the time the signal is
transmitted, so that the attending personnel know where to go. Numerous
other such applications for emergency transmitters will be apparent, such
as lost hikers, kidnap victims, lost children, trapped or stranded
individuals, and any person needing assistance when there is no access to
conventional channels of communication (e.g., telephones, cell phones).
[0005] Emergency transmitters are generally helpful in such situations, as
they are relatively easy to activate (even for a child, or a distressed
or ill person) and can function when other forms of communication such as
telephones and cell phones are not functioning or are otherwise not an
option for the person requiring assistance.
[0006] However, in cases where the person requiring assistance must be
particularly covert in their signaling for help, conventional emergency
transmitters are problematic. For example, consider the case where a
soldier is trapped or imprisoned behind enemy lines. An RF transmission
from that soldier would likely be intercepted, thereby compromising the
soldier's emergency transmission as well as his position. In such a case,
use of a flashlight as an emergency transmitter may be helpful and more
covert than an RF transmission, but conventional flash lights tend to be
bulky and are limited for purposes of communication.
[0007] In addition, conventional emergency transmitters are prone to use
by enemy or otherwise unfriendly personnel. Thus, should such a
transmitter fall into enemy hands, a false transmission can be sent,
thereby luring rescuing personnel into a trap or an otherwise adverse
situation.
[0008] What is needed, therefore, is a semi-covert emergency transmitter
for soldiers and other such personnel requiring rescue.
SUMMARY OF THE INVENTION
[0009] One embodiment of the present invention provides a semi-covert
emergency transmitter device. The device includes a microphone for
receiving verbal input, and converting that verbal input to an electrical
signal. The verbal input can be, for instance, a key phrase required to
initiate transmission of an emergency message, or a message for
transmission. A verification module is adapted for verifying the verbal
input was provided by an intended user. In one particular configuration,
the verification module is implemented as voice recognition module
adapted. A processor is adapted to provide a coded message in response to
the verification module verifying the verbal input was spoken by the
intended user. A light source is used for transmitting the coded message
provided by the processor. The light source can be, for example, an light
emitting diode (LED) or a laser. In one particular configuration, the
processor has a transmit mode and a flashlight mode, with each mode being
initiated by a user input requesting a particular mode. In the flashlight
mode, the processor turns the LED on to provide an illumination source.
The device may further include an analog to digital converter that is
adapted to convert the electrical signal from the microphone into its
digital equivalent, and to provide that digital signal to at least one of
the processor and verification module. The device may further include a
translation module that is adapted to convert the verbal input into a
coded form that can be at least one of stored in a memory of the device
and transmitted by the light source. The processor can be further adapted
to provide the coded message only in response to the verbal input being
spoken by the intended user a pre-defined number of times (e.g., where
the verbal input is a key phrase that is spoken three times in a row to
initiate transmission). The coded message can be stored in a memory
accessible by the processor. Note that the verification module can be
programmed or otherwise integrated into the processor.
[0010] Another embodiment of the present invention provides a method for
semi-covert emergency transmission. The method includes receiving an
electrical signal representative of a verbal input, and verifying the
verbal input was provided by an intended user. In response to verifying
the verbal input was spoken by the intended user, the method further
includes transmitting a coded message using a light source (e.g., LED or
miniature bulb or laser), thereby signaling a need for help in a
semi-covert manner relative to radio frequency transmissions. The method
may further include converting the verbal input into a coded form that
can be at least one of stored in a memory of the device and transmitted
by the light source. Verifying the verbal input was provided by an
intended user may include, for example, at least one of performing voice
recognition on the verbal input and ensuring the verbal input was spoken
a pre-defined number of times.
[0011] The features and advantages described herein are not all-inclusive
and, in particular, many additional features and advantages will be
apparent to one of ordinary skill in the art in view of the drawings,
specification, and claims. Moreover, it should be noted that the language
used in the specification has been principally selected for readability
and instructional purposes, and not to limit the scope of the inventive
subject matter.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] FIGS. 1a, 1b, and 1c show pictorial views of a semi-covert
emergency transmitter configured in accordance with one embodiment of the
present invention.
[0013] FIG. 2 shows a block diagram a semi-covert emergency transmitter
circuit configured in accordance with one embodiment of the present
invention.
[0014] FIG. 3 shows a method for carrying out a semi-covert emergency
transmission in accordance with one embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0015] Embodiments of the present invention provide a semi-covert
emergency transmission device and methodology for soldiers and other such
personnel requiring pick-up or rescue. The device has a flashlight mode
and a transmit mode. In flashlight mode, an LED is turned on to provide
an illumination source that can be used in numerous applications. In
transmit mode, the device uses the same LED to transmit a coded message
that includes information relevant to the user.
[0016] For example, a soldier trapped behind enemy lines can use the
device to transmit his name and other select personal information in
Morse code (or some other established code) so that a nearby friendly
aircraft or forces can detect the message and arrange for rescue of the
soldier. The coded message can be preprogrammed and stored into the
device, so that the soldier only needs to depress a transmit button to
activate the transmission process.
[0017] In addition, the transmit mode is further configured so as to
confirm that the intended soldier is the one requesting the transmission
of the coded message. This confirmation can be carried out, for example,
by requiring the soldier to recite a key phrase into a microphone of the
device, and then performing voice recognition to ensure that the soldier
is the one who recited the key phrase. Numerous security schemes can be
used here, as will be apparent in light of this disclosure.
[0018] The light emitted from the LED can be seen for up to a mile or so
away by friendly forces or other potential rescuers. At the same time,
interception of the semi-covert emergency signal by unfriendly forces is
less likely due to the localized nature of the light emitting from the
LED, as compared to an RF emergency transmission. The device may further
be configured with translation capability, so that messages spoken by the
user are coded in real-time, to provide greater flexibility in the
messages that can be transmitted.
[0019] Device Architecture
[0020] FIGS. 1a, 1b, and 1c show pictorial views of a semi-covert
emergency transmitter configured in accordance with one embodiment of the
present invention. As can be seen, the device includes a housing 105
configured with a transmit button 110, a flashlight button 115, a
microphone port 120, and an LED port 125.
[0021] The housing 105 can be fabricated, for example, from injection
molded plastic or machined aluminum or steel. The transmit button 110 and
the flashlight button 115 can be implemented with, for instance,
conventional push button switches. Each of the switches 110 and 115 can
be covered with a supple rubber cover to protect the respective
underlying switch. The microphone port 120 and the LED port 125
correspond to the position of microphone and LED components,
respectively, within the housing 105. These internal circuit components,
as well as other device circuitry, will be discussed in reference to FIG.
2.
[0022] This example housing embodiment is relatively compact compared to
conventional transmission devices, measuring about two inches in length
by one and half inches wide, and is under one half inch in thickness.
Thus, the device could readily be stored in a pocket or pack of the user,
or otherwise concealed on the user's person. Smaller or larger form
factors can be realized here, and the present invention is not intended
to be limited to any one such size or configuration.
[0023] FIG. 2 shows a block diagram a semi-covert emergency transmitter
circuit configured in accordance with one embodiment of the present
invention. The circuit includes a processor 205, a memory 210, a voice
recognition module 215, a power module 220, a microphone 230, an LED 235,
and an analog to digital converter (ADC) 240. An optional translation
module 225 can also be provided. Each of the components can be mounted on
a printed wire circuit board, with conductor runs interconnecting the
components as necessary, as is conventionally done.
[0024] The processor 205 can be implemented with conventional technology,
such as a field programmable gate array (FPGA), application specific
integrated circuit (ASIC), or a microcontroller, and is programmed or
otherwise configured to coordinate the overall function of the device as
discussed herein. The processor 205 operates in two modes: flashlight
mode and transmit mode.
[0025] In operation, the processor 205 enters the flashlight mode when it
receives input from the flashlight button 115. For instance, when the
flashlight button 115 switches from its off state to its on state, the
processor 205 responds by switching power to the LED 235, thereby turning
the LED 235 on. In this example configuration, the power that is switched
to the LED 235 by the processor 205 is provided by power module 220,
which can be a battery or other conventional power source. The LED 235
will remain on until the flashlight button 115 switches to its off state,
or until the processor enters the transmit mode.
[0026] The processor 205 enters the transmit mode when it receives input
from the transmit button 110. For instance, when the transmit button 110
switches from its off state to its on state, the processor 205 responds
by waiting for the user to speak a key phrase into the microphone 230.
The key phrase can be any pre-established word or group of words. The
microphone 230 converts the spoken key phrase into an analog signal, and
ADC 240 converts that signal to its digital equivalent (e.g., with 8 to
32 bit resolution, depending on desired conversion accuracy). The digital
signal is then provided to the processor 205 for analysis.
[0027] In this embodiment, the processor 205 passes the digital signal to
the voice recognition module 215, which can be implemented with
conventional technology, such as that used in cell phone applications
configured with voice recognition. The voice recognition module 215 then
determines if the spoken key phrase was actually spoken by the intended
user of the device. For example, the voice recognition module 215 can be
configured to digitally compare a previously recorded sample of the
intended user's voice with the spoken key phrase. The previously recorded
sample can be, for instance, the key phrase or a series of words and
sounds sufficient to provide the module 215 with a baseline to perform
the comparison.
[0028] Note that either the processor 205 or the voice recognition module
215 can also be programmed or otherwise configured to require the key
phrase to be spoken a pre-defined number of times (e.g., three times)
before proceeding with the transmit process. Other confirmation and
security schemes can be used here as well, such as entry of a multi-digit
code using a keypad (not shown), or requiring a specific number of finger
taps at the microphone port 120, properly spaced in time (e.g., according
to a melody or other established cadence).
[0029] Once the request for transmit mode is verified as legitimate, the
processor 205 then retrieves emergency transmit information from the
memory 210. In one embodiment, this emergency transmit information
includes the user's name, social security number, and mother's maiden
name, and is stored in a coded form, such as in Morse code or some other
established code that can be transmitted using LED 235. In general, the
emergency transmit information can be any message that can communicates
or is otherwise established as a signal for assistance.
[0030] The processor 205 then provides that coded emergency transmit
information to the LED, thereby causing the LED 235 to flash on and off
in accordance with the coded emergency transmit information. The
processor 205 can be further configured to transmit the coded message a
number of times (e.g., twice) before exiting the transmit mode, with a
small delay (e.g., 10 seconds) between each transmission. After
transmission is complete, the device can go into a dormant mode, or can
go back into flashlight mode (assuming it was in flashlight mode prior to
the transmission).
[0031] The device can also be configured with the optional translation
module 225, which would allow messages spoken into the microphone to be
translated into code. In one particular embodiment, the optional
translation module 225 is programmed or otherwise configured to convert
digital equivalents of the spoken messages captured by microphone 230
into Morse code or any other established code that can be communicated by
LED 235. The optional translation module 225 could be configured, for
example, with a digital library of previously spoken common words known
to the user, with each of the stored words associated with its coded
equivalent. Thus, when the user speaks any combination of those stored
words, the translation module 225 can digitally compare each word
received (e.g., in digital format from ADC 240) with the library of words
to identify the corresponding codes. The set of words in the library can
be set as desired. The coded messages can then be provided to the
processor 205 for transmission via the LED 235, or for storage in memory
210.
[0032] Note that the example configuration shown in FIG. 2 has various
functionality in separate modules. Other configurations are possible
here, where one or more of the modules (or their functionality) are
integrated with other modules. For example, assume that processor 205 is
implemented with a microcontroller unit (MCU) configured with a
processor, memory, a number of I/O ports, and programmable functionality.
Here, memory 210 could be included in the MCU. Also, each of the voice
recognition module 215 and the optional translation module 225 could be
implemented as a process (e.g., set of executable instructions) running
on the processor of the MCU. Other suitable processing environments will
be apparent in light of this disclosure.
[0033] Other processes and functionality may also be included in the
processor 205, such as the ADC 240 for receiving analog input from the
microphone 230, and converting that input to its digital equivalent.
[0034] Also, a third button could be provided on the housing 105, such as
a program button that could be pressed and held during programming of the
device. In one such case, the processor 205 would receive the programming
signal from the programming button, thereby causing the processor 205 to
wait for digitized verbal input from the microphone 230 and ADC 240. Such
a feature would allow a user to, for example, program the key phrase or
an emergency transmit message, or to stock the voice recognition module
215 with sample voice data. Once the programming button was released, the
processor 205 would go back to its dormant mode and wait for user input.
Note that the initial programming of the device can be carried out
without taking security measures, but subsequent re-programming can be
protected by a security scheme, where certain tests (e.g., key phrase and
voice recognition) must be passed before the re-programming is allowed.
[0035] Also, a power conservation routine can be programmed into processor
205, where the device stays in a low power sleep mode until input from a
user is received, thereby extending the life of power module 220. For
example, only the processor would be provided with power from the power
module 220 during sleep mode. If user input is received by the processor
205, then the power conservation routine running therein can be
configured to connect power to only portions of the circuit that are
required to carry out the requested functionality. For instance, if
flashlight mode is requested, power from module 220 is provided to the
processor 205 and LED 235 only. If transmit mode is requested, then
processor 205, voice recognition module 215, microphone 230, ADC 240, and
optional translation module 235 (if included) would be powered until user
verification was completed, and then only the processor 205 and LED 235
would be powered while the transmission was carried out (assuming
verification passed). Numerous power conservation schemes can be used
here.
[0036] Methodology
[0037] FIG. 3 shows a method for carrying out a semi-covert emergency
transmission in accordance with one embodiment of the present invention.
The method can be carried out or otherwise directed, for instance, by the
processor 205 of the semi-covert emergency transmission device shown in
FIG. 2.
[0038] The method begins with receiving 305 user input (e.g., via the
flashlight button or the transmit button). The method continues with
determining 310 if the flashlight mode is being requested or deactivated.
If so, then the method continues with turning 315 an LED (or other
suitable light source that can be used to notify friendly forces) on or
off. If the flashlight mode is not being requested or deactivated, then
the method continues with determining 320 if the transmit mode is being
requested. If not, then the method continues with waiting 325 for valid
user input.
[0039] If the transmit mode is being requested, then the method continues
with determining 330 if a key phrase spoken into the device is correct
(e.g., where the user is required to say "red" three times into the
microphone 230). If not, then the method continues with waiting 325 for
valid user input. If the key phrase spoken into the device is correct,
then the method continues with determining 335 if the voice that spoke
the key phrase is recognized (e.g., using conventional voice recognition
technology). Note that the method may further include converting the
spoken key phrase into digital format to facilitate its processing in
steps 330 and 335.
[0040] If the voice that spoke the key phrase is not recognized, then the
method continues with waiting 325 for valid user input. If the voice that
spoke the key phrase is recognized, then the method continues with
transmitting 340 emergency information (e.g., using LED 235). Note that
the method may further include retrieving the emergency information from
a memory (e.g., memory 210) where it is stored in a coded format that is
capable of transmission by the LED. This transmitting can be repeated a
number of times, as desired. The transmission may also be cancelled if so
desired (e.g., by pressing the transmit button again).
[0041] Variations on the method will be apparent in light of this
disclosure. For instance, if the flashlight mode was enabled prior to the
occurrence of waiting 325 for user input, then it can be configured to
remain enabled (so that the flashlight stays on if a failed request for
transmission occurs).
[0042] Also, the method may further include an anti-tamper feature, where
if the transmit mode is entered and the key phrase and/or voice
recognition tests fail more than a pre-defined number of times, then the
device can be configured to shut down or take some other defensive
action. Also, the method may further include a programming mode that
allows a user to program or re-program the device.
[0043] Also, note that light sources other than an LED can be used to
communicate a discreet message. For instance, the light source could be
miniature light bulb. Alternatively, the light source could be a laser,
such as those used in a laser pointer. In such an application, the laser
could be visible laser light that could be seen or otherwise detected by
potential rescuers. Alternatively, the laser light could be on the
invisible end of the spectrum, and could be used in conjunction with
detectors designed to detect the transmitted emergency laser information.
The detectors could be deployed on the bottom of friendly aircraft or on
the ground at strategic locations proximate the user's field of
operation.
[0044] The foregoing description of the embodiments of the invention has
been presented for the purposes of illustration and description. It is
not intended to be exhaustive or to limit the invention to the precise
form disclosed. Many modifications and variations are possible in light
of this disclosure. It is intended that the scope of the invention be
limited not by this detailed description, but rather by the claims
appended hereto.
* * * * *
