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| United States Patent Application |
20060007020
|
| Kind Code
|
A1
|
|
Biermann; Paul J.
|
January 12, 2006
|
Method and apparatus for covertly detecting and reporting a distress
condition in a vehicle control cabin
Abstract
A method of covertly detecting and reporting a distress condition in a
control cabin of a vehicle, the cabin having designated areas expected to
be occupied by respective operators under normal operating conditions of
the vehicle. The method comprises (a) attaching to each operator a
transponder tag configured to wirelessly transmit a response signal,
unique to the operator to which it is attached, responsive to an
interrogator signal; (b) wirelessly transmitting interrogator signals
into the designated areas; (c) attempting to detect response signals, if
any, from the transponder tags; and (d) if all of the response signals
are concurrently not detected, then wirelessly transmitting a distress
signal from the vehicle.
| Inventors: |
Biermann; Paul J.; (Columbia, MD)
|
| Correspondence Name and Address:
|
Albert J. Fasulo, II;Office of Patent Counsel
The Johns Hopkins University Applied Physics Lab
11100 Johns Hopkins Road, Mail Stop 7-156
Laurel
MD
20723-6099
US
|
| Serial No.:
|
888460 |
| Series Code:
|
10
|
| Filed:
|
July 9, 2004 |
| U.S. Current Class: |
340/945; 340/426.1; 340/5.2; 340/572.1; 340/574 |
| U.S. Class at Publication: |
340/945; 340/426.1; 340/574; 340/572.1; 340/005.2 |
| Intern'l Class: |
G08B 21/00 20060101 G08B021/00; B60R 25/10 20060101 B60R025/10 |
Claims
1. A method of covertly detecting and reporting a distress condition in a
control cabin of a vehicle, the cabin having designated areas expected to
be occupied by respective operators under normal operating conditions of
the vehicle, comprising: (a) attaching to each operator a transponder tag
configured to wirelessly transmit a response signal, unique to the
operator to which it is attached, responsive to an interrogator signal;
(b) wirelessly transmitting interrogator signals into the designated
areas; (c) attempting to detect response signals, if any, from the
transponder tags; and (d) if all of the response signals are concurrently
not detected, then wirelessly transmitting a distress signal from the
vehicle.
2. The method of claim 1, wherein the cabin includes cabin-installed,
mechanically activated panic buttons each positioned within or near to a
respective one of the designated areas for access by the respective
operator, the method further comprising: (e) between steps (c) and (d),
determining if any of the panic buttons are activated; and (f) if at
least one of the panic buttons is activated and at least one of the
response signals is detected, then transmitting a distress signal from
the vehicle.
3. The method of claim 2, further comprising repeating steps (b) through
(f) until either (i) at least one of the panic buttons is activated, or
(ii) all of the response signals are not detected concurrently.
4. The method of claim 1, wherein the vehicle includes one or more
engines, the method further comprising, before step (a): determining if
all of the one or more engines are turned on; and performing steps (a)
through (d) only if it is determined that all of the one or more vehicle
engines are turned on.
5. The method of claim 1, wherein step (b) comprises: wirelessly
transmitting a first of the interrogator signals from a first fixed
position into a first of the designated areas between a first operator
seat and an operator consol of the vehicle; and wirelessly transmitting a
second of the interrogator signals from a second fixed position into a
second of the designated areas between a second operator seat and the
operator console.
6. The method of claim 5, wherein the vehicle is an airplane, the
operators include a first pilot and a second pilot of the airplane, and
the cabin is a cockpit of the airplane, wherein step (b) comprises:
wirelessly transmitting the first of the interrogator signals from a
cockpit flight console toward a first pilot seat for the first pilot; and
wirelessly transmitting the second of the interrogator signals from the
cockpit flight console toward a second pilot seat for the second pilot.
7. The method of claim 6, wherein step (b) further comprises: wirelessly
transmitting the first of the interrogator signals toward the first pilot
seat using a first directive antenna; and wirelessly transmitting the
second of the interrogator signals toward the second pilot seat using a
second directive antenna.
8. The method of claim 5, wherein the vehicle is an airplane, the
operators include a first pilot and a second pilot of the airplane, and
the cabin is a cockpit of the airplane, wherein step (b) comprises:
wirelessly transmitting the first of the interrogator signals from a
first pilot seat for the first pilot; and wirelessly transmitting the
second of the interrogator signals from a second pilot seat for the
second pilot.
9. The method of claim 5, wherein step (b) further comprises wirelessly
transmitting each of the first and second interrogator signals at a power
level of less than or equal to 0.1 Watts.
10. The method of claim 9, wherein step (b) further comprises wirelessly
transmitting each of the first and second interrogator signals in a
frequency range of about 800 to 1000 MHz.
11. The method of claim 1, wherein the vehicle is an airplane, the
operators include a first pilot and a second pilot of the airplane, and
the cabin is a cockpit of the airplane.
12. The method of claim 1, comprising: wirelessly transmitting at least
one uniquely encoded response signal responsive to at least one of the
interrogator signals.
13. The method of claim 1, wherein step (d) comprises wirelessly
transmitting a distress message formatted to indicate that all of the
operators are absent from their designated areas in the cabin.
14. A method of covertly detecting and reporting a distress condition in a
cockpit of an airplane, the cockpit having designated areas expected to
be occupied by respective pilots under normal operating conditions of the
vehicle, comprising: (a) attaching to each pilot a transponder tag
configured to wirelessly transmit a response signal, unique to the pilot
to which it is attached, responsive to an interrogator signal; (b)
wirelessly transmitting interrogator signals into the designated areas;
(c) attempting to detect response signals, if any, from the transponder
tags; and (d) if all of the response signals are concurrently not
detected, then wirelessly transmitting a distress signal from the
aircraft.
15. A system for covertly detecting and reporting an emergency condition
in a control cabin of a vehicle, the cabin having designated areas
expected to be occupied by respective operators under normal operating
conditions of the vehicle, comprising: transponder tags each configured
to (i) be attached to a respective operator, and (ii) wirelessly transmit
a response signal, uniquely encoded to identify the operator to which it
is attached, responsive to an interrogator signal; interrogator units,
each including a transmitter configured to wirelessly transmit an
interrogator signal, a receiver configured to detect a wireless response
signal if received, and a controller, coupled with the receiver,
configured to issue a result message indicating whether a response signal
is detected; a control module configured to issue a distress message when
the result messages issued from all of the interrogators indicate that
all of the response signals are not detected concurrently; and a radio
configured to wirelessly transmit the distress message.
16. The system of claim 15, wherein: a first of the interrogator units is
mounted to an operator panel of the cabin, and configured to transmit a
first of the interrogator signals toward a first operator seat; a second
of the interrogator units is mounted to the operator panel of the cabin,
and configured to transmit a second of the interrogator signals toward a
second operator seat.
17. The system of claim 16, wherein each of the interrogator units
includes a directional transmit antenna having maximum antenna gain
directed toward a respective one of the operator seats.
18. The system of claim 15, wherein the vehicle is an airplane, the
operators include a first pilot and a second pilot of the airplane, and
the cabin is a cockpit of the airplane.
19. The system of claim 18, wherein: a first of the interrogator units is
mounted to a first portion of a cockpit control console, and configured
to transmit a first of the interrogator signals toward a first pilot seat
for the first pilot; and a second of the interrogator units is mounted to
a second portion of the cockpit control console, and configured to
transmit a second of the interrogator signals toward a second pilot seat
for the second pilot.
20. The system of claim 18, wherein: a first of the interrogator units is
mounted to a first pilot seat for the first pilot, and configured to
transmit a first of the interrogator signals from the first pilot seat
into a first of the designated regions; and a second of the interrogator
units is mounted to a second pilot seat for the second pilot, and,
configured to transmit a second of the interrogator signals from the
second pilot seat into a second of the designated regions.
21. The system of claim 15, wherein: the cabin includes mechanically
activated panic buttons each coupled with the control module and
positioned within a respective one of the designated areas for access by
the respective operator; and the control module is coupled to the panic
buttons and is configured to determine if any of the panic buttons are
activated, and issue a distress message when at least one of the panic
buttons is activated and at least one of the response signals is
detected.
22. The system of claim 15, wherein each of the transponder tags is a
passive tag type transponder configured to derive its full operating
power from one of the interrogator signals.
23. The system of claim 15, wherein the controller of each of the
interrogator units is configured to issue a message to the control module
indicating that the corresponding uniquely encoded response signal is
absent when the corresponding response signal has not been detected for
more than a predetermined maximum time period.
24. A system for covertly detecting and reporting an emergency condition
in a cockpit of an airplane, the cockpit having designated areas, between
a cockpit control console and pilot seats, expected to be occupied by
respective pilots under normal operating conditions of the airplane,
comprising: transponder tags each configured to (i) be attached to a
respective pilot, and (ii) wirelessly transmit a response signal,
uniquely encoded to identify the pilot to which it is attached,
responsive to an interrogator signal; interrogator units each mounted to
either a respective portion of the cockpit control console that faces a
respective pilot seat, or a respective pilot seat, each of the
interrogator units including a transmitter configured to wirelessly
transmit an interrogator signal, a receiver configured to detect a
wireless response signal from a corresponding one only of the transponder
tags, and a controller, coupled with the receiver, configured to issue a
result message indicating whether the response signal is detected; a
control module configured to issue a distress message when the result
messages issued from all of the interrogators indicate that all of the
response signals are not detected concurrently; and a radio configured to
wirelessly transmit the distress message.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application relates to U.S. Provisional Application Ser. No.
60/432,524, filed Dec. 11, 2002, which is incorporated herein by
reference in its entirety.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to detecting and reporting emergency
distress conditions in a control cabin of a transportation vehicle.
[0004] 2. Background
[0005] Since September 11, terrorist attacks directed against mass
transportation vehicles, such as airplanes, trains and even buses, have
increased in frequency with often devastating results. This disturbing
trend seems likely to continue into the foreseeable future. Typically, a
transportation vehicle includes a control cabin having vehicle operators
occupying designated areas during normal operating conditions of the
vehicle. Terrorists must breach the control cabin, and often remove the
operators from their designated areas, in order to rest control of the
vehicle from the operators. The operators may be powerless to notify
others of the attack, or even killed attempting to do so. Thus, in a
transportation vehicle housing operators, there is an ever pressing need
to covertly detect and report emergency conditions, such as an
unauthorized breach of the control cabin, or the unauthorized removal of
all of the operators from their designated areas, by terrorists.
SUMMARY OF THE INVENTION
[0006] An embodiment of the present invention includes a method of
covertly detecting and reporting a distress condition in a control cabin
of a vehicle, the cabin having designated areas expected to be occupied
by respective operators under normal operating conditions of the vehicle.
The method comprises (a) attaching to each operator a transponder tag
configured to wirelessly transmit a response signal, unique to the
operator to which it is attached, responsive to an interrogator signal;
(b) wirelessly transmitting interrogator signals into the designated
areas; (c) attempting to detect response signals, if any, from the
transponder tags; and (d) if all of the response signals are concurrently
not detected, then wirelessly transmitting a distress signal from the
vehicle.
[0007] Further method, system and apparatus embodiments are apparent from
the description below.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008] Various embodiments are described below with reference to the
drawings.
[0009] FIG. 1 is an example transportation system or environment in which
the present environment can operate.
[0010] FIG. 2 is a schematic block diagram of an example system of the
present invention, corresponding to the arrangement depicted in FIG. 1.
[0011] FIG. 2A is a block diagram of an example alternative arrangement of
a system of the present invention.
[0012] FIG. 3 is a block diagram of an example arrangement of a
transponder from FIGS. 1 and 2.
[0013] FIG. 4 is a block diagram of an example arrangement of an
interrogator unit from FIGS. 1 and 2.
[0014] FIG. 5 is a circuit diagram of an arrangement of a cabin-mounted
mechanically activated panic button from FIGS. 1 and 2.
[0015] FIG. 5A is an example message format for a distress message
transmitted from a vehicle of FIG. 1.
[0016] FIG. 6 is a flow chart of an example method of the present
invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)
[0017] A transportation vehicle typically includes a control cabin having
designated areas expected to be occupied by operators under normal
operating conditions of the vehicle. The present invention presents a
method and apparatus/system for detecting and reporting an emergency or
distress condition in the control cabin, such as, but not limited to, an
unauthorized absence of the operators from their designated areas, or an
unauthorized intrusion into the cabin by, for example, a terrorist, as
will be described below by way of an airplane example. It is to be
understood that the present invention may operate in connection with any
mass transportation vehicle, such as a train, bus, cruise ship, etc.,
having a control cabin occupied by multiple operators.
[0018] FIG. 1 is an illustration of an example transportation system or
environment 100 in which the present environment can operate. System 100
includes an aircraft 102 depicted in flight, and a ground station 106,
such as an air traffic control tower. Depicted in FIG. 1 is a top
interior view of a control cabin or cockpit 104 of airplane 102.
[0019] Under normal flight operating conditions, pilots 110a and 110b
occupy respective seats 112a and 112b in cabin 104. Pilots 110 control
aircraft 102 through flight control sticks 114, and cockpit control
console 116. Cabin 104 also includes a radio 120 for wirelessly
transmitting messages to and receiving messages from ground station 106
over a radio link 108. Control console 116 includes a console face 122
having portions 122a and 122b facing respective seats 112a and 112b,
thereby defining respective designated areas or regions 128a and 128b.
Under normal flight conditions, pilots 10a and 110b occupy respective
designated areas 128a and 128b. Although only two pilots are depicted,
more pilots and corresponding designated areas may be present in any
given embodiment.
[0020] Arranged in cabin 104 are the following components constructed and
operated in accordance with the present invention to covertly detect and
report an emergency condition in the cabin: radio 120, interrogator units
124, transponder tags 130, optional cabin-mounted panic buttons 140 and a
control module 126, which communicates with radio 120. The present
invention is intended to uncover covertly emergency conditions such as,
but not limited to, the forcible removal of all of pilots 110 from their
seats, i.e., from their designated areas 128, and the intrusion into
cabin 104 of an unauthorized person, such as a terrorist, for example.
[0021] FIG. 2 is a schematic block diagram of an example system 200
including interrogator modules 124, transponder tags 130, panic buttons
140, control module 126 and radio 120, corresponding to the arrangement
depicted in FIG. 1. With reference to FIGS. 1 and 2, interrogator unit
124a, mounted to or within console face portion 122a, wirelessly
transmits an interrogator signal 210a into designated area 128a.
Interrogator unit 124a preferably transmits interrogator signal 210a (i)
at a transmit power level sufficiently low, and (ii) with sufficient
directivity within designated area 128a, so as to substantially limit the
detectable range of the interrogator signal to that designated area.
Similarly, interrogator unit 124b, mounted to console face portion 122b,
wirelessly transmits an interrogator signal 210b into designated area
128b (i) at a transmit power level sufficiently low, and (ii) with
sufficient directivity within designated area 128b, so as to
substantially limit the detectable range of the interrogator signal to
that designated area.
[0022] Pilots 110a and 110b wear respective transponder tags 130a and 130b
paired with or corresponding to respective interrogator units 124a and
124b. Transponder tag 130a, if within the detectable range of
interrogator signal 210a, i.e., if in designated area 128a, wirelessly
transmits a response signal 212a uniquely encoded to identify pilot 110a,
responsive to interrogator signal 210a. Similarly transponder tag 130b,
if within the detectable range of interrogator signal 210b, i.e., if in
designated area 128b, wirelessly transmits a response signal 212b
uniquely encoded to identify pilot 110b, responsive to interrogator
signal 210b. Interrogator units 124 process respective response signals
212.
[0023] Airplane cabin 104 also includes cabin-installed, mechanically,
e.g., pressure, activated panic buttons 140a and 140b, which may be
mounted, e.g., to a floor of cabin 104 near the feet of respective pilots
110a and 110b. Pilots 110 may strike, e.g., kick, panic buttons 140 to
activate the panic buttons.
[0024] Control module 126 operates in accordance with the present
invention to control system 200. Control module 126 includes one or more
computer controllers, memory for storing computer code that the computer
controller(s) execute, signal input/output interfaces, and so on, as is
known. Control module 126 may be either a stand-alone unit, or included
as part of, i.e., integrated with, existing airplane control computers.
Control module 126 issues to radio 120 messages destined for ground
station 102, and in turn, radio 120 wirelessly transmits the messages to
the ground station. Radio 120 may be either a stand-alone radio, or a
known cockpit radio, such as a transponder radio, equipped to receive and
transmit the messages from control module 126 in accordance with the
present invention.
[0025] Ground station 106 includes a radio 160 for receiving messages from
and transmitting messages to airplane 102 over link 108. Ground station
106 also includes an operator interface 162 to display to ground station
operators messages received over link 108, through radio 106, as is
known.
[0026] Control module 126 also communicates with interrogator units 124
and panic buttons 140 over interface links 204, which may be wired or
wireless. Control module 126 issues control commands to interrogator
units 124, and interrogator units 124 issue messages 206 to control
module 126, over corresponding interfaces 204. In particular, if either
interrogator unit 124a or 124b stops receiving corresponding tag response
signal 212a or 212b for more than a predetermined period of time,
indicating that the corresponding tag 130a or 130b, and thus pilot 110a
or 110b to which the tag is attached, is absent from designated area 128a
or 128b, then that interrogator unit sends a "Response Signal Absent"
(RSA) message to control module 126 indicating the absence of the
response signal. Substantially contemporaneous or concurrent receipt of
RSA messages from all interrogator units 124 indicates a concurrent
absence of all of pilots 110 from designated areas 128. The RSA message
represents a "results message" indicative of whether the interrogator
unit detected a response signal. The concurrent absence of all of pilots
110 from designated areas 128 is considered an emergency condition. For
example, all of pilots 110 may have been forcibly removed from their
seats by a terrorist in a hijack scenario.
[0027] Additionally, control module 126 receives sensed signals 213a-213n
from corresponding airplane component sensors, indicative of various
conditions of the airplane. For example, sensed signal 213a indicates
whether the aircraft engine(s) are ON or OFF, and sensed signal 213b
indicates whether aircraft 102 is being supplied with ground power, for
example, when the aircraft is parked and being serviced at an airport.
Such sensed signals are available to cockpit electronics in conventional
systems.
[0028] FIG. 2A is a block diagram of an example alternative arrangement
258 of system 200 as depicted in cabin 104, wherein interrogator units
124a, 124b are mounted in respective back portions 260a, 260b of
respective seats 112a, 112b, instead of in console portion 116. In
arrangement 258, interrogator units 124a, 124b transmit signals 210a,
210b from seats 112a, 112b into designated areas 128a, 128b,
respectively. In other arrangements, interrogator units 124 may be
mounted to (i) lower horizontal seat portions 264 of seats 112, (ii)
control sticks 114, or (iii) the floor of cabin 102 near, e.g., under the
seats.
[0029] The operation of system 200 is now described. Initially, while
airplane 102 is grounded at an airport, control module 126 monitors
sensed signals 213a-213n. After take-off, control module 126 monitors
interrogator units 124 over interface 204. Interrogator units 124
transmit interrogator signals 212 and listen for response signals 212.
[0030] Under normal airplane operating conditions, at least one pilot
(e.g., pilot 110a) occupies his/her designated area (e.g., 128a). Thus,
at least that pilot's transponder tag (e.g., tag 130a) transmits a
response signal (e.g., signal 212a), and the corresponding interrogator
unit (e.g., unit 124a) receives the response signal. Because of the
continued presence of the response signal (e.g., signal 212a) the
corresponding interrogator unit (e.g., unit 124a) will not send an RSA
messages to control module 126. Thus, control module 126 will not receive
substantially concurrent RSA messages from all of interrogator units 124.
From this, control module 126 determines that an emergency condition does
not exist in cabin 104, because at least one pilot occupies his/her
designated area.
[0031] On the other hand, if control module 126 receives substantially
concurrent RSA messages from all of interrogator units 124, indicating
the concurrent absence of all tags 130, and thus pilots 110 to which the
tags are attached, from their designated areas, then control module 126
determines an emergency condition exists in cabin 104, and initiates the
sending of an "All Operators (e.g., Pilots) Absent" distress message to
ground station 106. Ground station 106 presents the message to ground
station operators. Thus, in this manner, system 200 automatically (i.e.,
without operator invention) detects and reports the emergency condition
in cabin 104 in a covert manner.
[0032] Control module 126 also monitors an activation status of panic
buttons 140. If control module 126 determines that either of panic
buttons 140 are activated, for example, by a pilot striking one of the
panic buttons, then control module 126 initiates the sending of a "Panic
Button Activated" distress message to ground station 102. For example,
pilot 10a may activate panic button 140a upon an unauthorized intrusion
by an individual into cabin 104. Ground station 106 presents the message
to ground station operators. Thus, in this manner, system 200 covertly
reports the emergency condition in cabin 104.
[0033] FIG. 3 is a block diagram of an example arrangement of transponder
tag 130a, which may be constructed on an integrated circuit chip. All of
the transponder tags (e.g., tags 130a and 130b) may be substantially
identical, with the exception that each tag generates a uniquely encoded
response signal. Transponder tag 130a includes an antenna coil 320 for
receiving interrogator signal 210a. In an embodiment, interrogator signal
210a is an RF carrier signal. Antenna coil 320 applies the RF carrier
signal to a rectifier/balanced modulator circuit 322 and a divide/timing
logic circuit 324 over a signal line 326.
[0034] Divide/timing logic circuit 324 divides the received carrier signal
to generate a clock signal and a second carrier signal on an output
signal line 328. The clock signal drives a data generator circuit 330,
which generates an encoded data word. The encoded data word is unique to
the transponder, and thus identifies the transponder. That is, each
transponder tag has its own unique encoded data word.
[0035] The encoded data word is presented over signal line 332 to the
rectifier/balanced modulator 322. Also presented to the
rectifier/balanced modulator 322, over signal line 334, is a buffered
carrier signal. The buffered carrier signal and the encoded data word are
mixed in the rectifier/balanced modulator 322 to produce a uniquely
encoded transmit signal that is presented on signal line 326 to antennal
coil 320, from which it is transmitted as the responsive signal 212a.
[0036] Transponder tag 124a is a passive tag type transponder configured
to derive its full operating power from interrogator signal 210a. To this
end, rectifier/balance modulator 322 rectifies incoming RF carrier signal
210a to generate operating power used by the divide/timing logic circuit
324 and data generator 330. This operating power is distributed to these
circuits over power lines 336 and 338, respectively.
[0037] Transponder tag 130a optionally includes a mechanically, e.g.,
pressure, activated panic button 348. Panic button 348 enables a user to
disable transponder tag 130a, i.e., render the tag non-responsive, by,
for example, simply striking the panic button. Panic button 348 includes
a mechanical activation component 350 coupled with an electronic switch
352. Mechanical activation component 350 selectively opens or closes
electronic switch 352 responsive to a pressure applied to the mechanical
activation component. Electronic switch 352 includes (i) a contact 352a
connected to antenna coil 320, (ii) a contact 352b, spaced from contact
352a, and connected to circuit 324, and (iii) a wiper 352c responsive to
mechanical activation component 350. When mechanical activation component
350 closes electronic switch 352, wiper 352c electrically connects
contact 352a to contact 352b (as depicted in solid line in FIG. 3), and
thus antenna coil 320 to circuit 324. When switch 352 is closed,
transponder 130a operates normally as described above. That is,
transponder 130a is responsive to interrogator signal 210a.
[0038] On the other hand, when mechanical activation component 350 opens
electronic switch 352, wiper 352c electrically disconnects contact 352a
from 352b (as depicted in dotted-line in FIG. 3), and thus antenna coil
320 from circuit 324. When switch 352 is open, transponder 130a is unable
to generate response signal 212a. That is, open switch 352 causes an
open-circuit between antenna coil 320 and divide/timing logic circuit
324, which inhibits or disables responsive operation of transponder 130a.
[0039] FIG. 4 is a block diagram of an example arrangement of interrogator
unit 124a. All of the interrogator units (e.g., units 124a and 124b) may
be substantially identical, with the exception that each interrogator
unit recognizes its corresponding uniquely encoded data word, as
described below. Interrogator unit 124a includes a transmitter 430 for
generating interrogator signal 210a at an approximate power level of 0.1
Watts or below, and an exemplary frequency in the range of about 800 to
1000 MegaHertz (MHz), although other powers and frequency ranges may be
used. Transmitter 430 includes a crystal oscillator 440, appropriate
transmitter circuitry 442, and a transmitter antenna or coil 444.
Transmitter 430 may generate interrogator signal 210a as a pulsed RF
signal having a relatively low duty cycle, for example. Alternatively,
interrogator signal 210a may be a continuous RF signal. In an embodiment,
antenna 444 is a directional antenna, such as a half-wavelength dipole,
quad-loop, or other directional antenna, having a maximum gain, i.e., an
antenna pattern main-lobe, directed toward seat 112a so as to overlap
designated area 128a. A similar arrangement holds for transponder tag
130b, which has an antenna main-lobe directed toward seat 112b. In
another embodiment, antenna 444 is not directional, i.e., antenna 444 is
an omni-directional antenna.
[0040] Interrogator unit 124a also includes a receiver 445 for receiving
response signal 212a. Interrogator unit 124a receives response signal
212a through an antenna coil 446 and receiver circuits 448 and 450 tuned
to the RF frequency of response signal 212a. Receiver circuits 448 and
450 pass a conditioned received signal to a demodulator/decoder circuit
452. Demodulator/decoder 452 demodulates and decodes the received signal
using known modulation and decoding techniques in order to extract the
data word signal included in responsive signal 212a. This data word
signal serves to identify the transponder unit (and thus pilot) from
which it originated. Circuit 452 provides the recovered data word, if
any, to an interrogator unit controller 460.
[0041] Interrogator unit controller 460 and a timer 462 operate together
to control the operation of transmitter 430 and receiver 445. Controller
460 includes a memory for storing, inter alia, timing information,
including a maximum predetermined time that response signal 212a can be
absent before an RSA message must be issued by the controller. In an
embodiment, controller 460 determines whether response signal 212a is
present or absent based on whether the data word is present or absent.
Controller 460 recognizes only the unique data word from the transponder
tag with which the interrogator unit is paired, e.g., controller 460 of
interrogator unit 124a recognizes only the unique data word from tag
130a, controller 460 of interrogator unit 124b recognizes only the unique
data word from tag 130b, and so on. Controller 460 uses a timing signal
from timer 462 to time the absences of the data word. When the data word
has been absent for a time period that exceeds the maximum predetermined
time allowed, then controller 460 issues an RSA message to control module
126 over interface 204. If and when controller 460 receives a next data
word after such an absence, then controller 460 issues a reset message to
computer module 126 indicating the presence of the response signal.
[0042] Except for the differences described above, each of interrogator
units 124 and each of transponder tags 130 may be constructed
substantially in accordance with controller/interrogator 12 and tag 14,
respectively, described in detail in U.S. Pat. No. 4,857,893 to Carroll,
incorporated herein by reference in its entirety.
[0043] FIG. 5 is a circuit diagram of an arrangement of cabin-mounted
mechanically activated panic button 140a. Panic button 140a includes
first and second spaced apart terminals 502 and 504. First terminal 502
is connected to a ground potential. A voltage rail 506 applies a rail
voltage +V to second terminal 504 through a pull-up resistor 508. Panic
button 140a also includes a movable, electrically conductive contact 510
having a first position corresponding to when panic button 140a is not
activated, depicted in FIG. 5, wherein contact 510 electrically connects
terminals 502 and 504. In this position, interface line 204c is held at
the ground potential, i.e., is pulled-low. Contact 510 can be moved in a
direction A away from terminals 502 and 504 to a second position
corresponding to when panic button 140a is activated, e.g., by a pilot,
thereby electrically disconnecting terminals 502 and 504. In this
position, interface line 204c is raised to voltage +V, i.e., is
pulled-high. Control module 126 determines when any of panic buttons 140
is/are activated. If any of panic buttons 140 is/are activated, control
module 126 initiates the sending of a distress message, as mentioned
above.
[0044] FIG. 5A is an example message format 560 for a distress message
transmitted from radio 120. Format 560 includes a priority field 562
indicating a high priority or distress message. A second field 564
indicates the type of distress condition, e.g., All Pilots Absent, or
Panic Button Activate.
[0045] FIG. 6 is a flow chart of an example method 600 of covertly
detecting an emergency condition in a control cabin of a transportation
vehicle, such as airplane cabin 104, for example, having operators who
occupy designated areas under normal operating conditions. Method 600
also summarizes the processes described above in connection with FIGS. 1
and 2.
[0046] A first step 602 includes determining whether all of the vehicle
engine(s) is/are ON or OFF. For example, control module 126 monitors
sensed signal 213a to determine if the airplane engines are ON or OFF. If
the engines are not turned ON, then flow returns to the start.
[0047] Otherwise, if the engines are turned ON, flow proceeds to an
optional next step 604, applicable to the airplane example described
above, which includes determining whether the vehicle is connected to
ground power. For example, control module 126 monitors sensed signal 213b
for the presence of ground power. Ground power may be provided to
airplane 102 while the airplane is grounded and being serviced at an
airport, for example. If ground power is present, then flow proceeds back
to step 604.
[0048] Otherwise, if ground power is not present, then flow proceeds to a
next step 606, which includes interrogating transponder tags attached to
the operators. For example, interrogator units 124 transmit signals 210
to interrogate corresponding transponder tags 130.
[0049] A next step 608 includes determining whether any transponder tag
responses are detected. For example, interrogator units 124 listen for
response signals 212 from tags 130. If any of response signals 212 is/are
not detected, i.e., is/are absent, for longer than a predetermined
maximum time, then the corresponding interrogator unit(s) send RSA
messages to control module 126 indicating the absence of the
corresponding response signal (and thus, transponder tag). In an
embodiment where transponder tags 130 include panic buttons (348), the
absence of a response signal may result from a pilot striking the
transponder tag panic button.
[0050] If no transponder tag responses are detected, then flow proceeds to
a next step 610, which includes transmitting a distress signal. For
example, if all of interrogator units 124 send substantially concurrent
RSA messages to control module 126 because none of response signals 212
are detected, then control module 126 issues the "All Pilots Absent"
distress message to radio 120, and radio 120 transmits the distress
message to ground station 106.
[0051] If at least one transponder tag response is detected at step 608,
then flow proceeds to a next step 612, which includes determining whether
any panic buttons have been activated. For example, if control module 126
has not received concurrent RSA messages from all of interrogator units
124, then control module 126 determines if any of panic buttons 140 have
been activated. If any of the panic buttons have been activated, then
flow proceeds to step 610, and the distress signal "Panic Button
Activated" is transmitted.
[0052] Otherwise, if none of panic buttons 140 have been activated, flow
proceeds back to step 606.
[0053] While the above description contains many specifics, these
specifics should not be construed as limitations of the invention, but
merely as exemplifications of preferred embodiments thereof. Those
skilled in the art will envision many other embodiments within the scope
and spirit of the invention as defined by the claims appended hereto.
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