This application is a continuation of U.S. patent application Ser. No. 11/506,787 filed on Aug. 21, 2006, which is a division of U.S. patent application Ser. No. 10/820,013 filed on Apr. 8, 2004, now U.S. Pat. No. 7,093,314, which is a continuation-in-part of U.S. patent application Ser. No. 10/394,242 filed Mar. 24, 2003, now U.S. Pat. No. 6,907,635, which is a continuation-in-part of U.S. patent application Ser. No. 10/139,376 filed May 7, 2002, now U.S. Pat. No. 6,637,063.
FIELD OF THE INVENTION The instant invention relates generally to docking systems for aircraft, and more particularly to a beacon docking system for aligning one end of a passenger loading bridge to a doorway of an aircraft.
BACKGROUND In order to make aircraft passengers comfortable, and in order to transport them between an airport terminal and an aircraft in such a way that they are protected from the weather and other environmental influences, passenger loading bridges are used which can be telescopically extended and the height of which is adjustable. For instance, an apron drive bridge in present day use comprises a plurality of adjustable modules, including: a rotunda, a telescopic tunnel, a bubble section, a cab, and elevating columns with wheel carriage. Of course, other types of bridges are known in the art, such as for example nose loaders, radial bridges, pedestal bridges, dual bridges and over the wing bridges. Additionally, multiple doorways along a same side or opposite sides of the aircraft may be serviced at a same time, for example using the over the wing bridge or two separate bridges.
Manual, semi-automated and automated bridge alignment systems are known for adjusting the position of a passenger loading bridge relative to a doorway of an aircraft, for instance to compensate for different sized aircraft and to compensate for imprecise parking of the aircraft at an airport terminal, etc.
Often, manual bridge alignment systems are preferred by the airlines because a trained bridge-operator is present and is able to observe directly the movements of the bridge relative to the doorway of the aircraft. Typically, the bridge-operator uses a control panel located within the cab section to adjust the bridge each time a flight arrives. Accordingly, the probability that the bridge will collide with an aircraft during an alignment operation is relatively small.
Of secondary concern to the airlines is ensuring that the passenger loading bridge is aligned with the doorway of the aircraft as rapidly as possible, thereby minimizing the time that is required to complete passenger deplaning, cleaning, restocking etc. As such, semi-automated bridge alignment systems are known in the prior art, which systems allow the bridge to be moved rapidly to a preset position under the control of a programmable controller or embedded control system. For example, some passenger loading bridges are equipped with controls that automatically cause the height adjustment mechanism to move the cab to a predetermined height. Unfortunately, the bridge-operator must be present to press a switch for enabling the automated height adjustment. As such, the bridge-operator must arrive at the passenger loading bridge in advance of the aircraft, which wastes the time of the bridge-operator, or alternatively the bridge-operator initiates the height adjustment after the aircraft has arrived at the passenger loading bridge, which inconveniences the passengers waiting on board the aircraft.
Schoenberger et al. in U.S. Pat. No. 5,226,204 discloses a semi-automated passenger loading bridge that uses video cameras in the control of the passenger loading bridge. The system maneuvers a movable end of the bridge to a position close to the doorway of the aircraft, whereupon an operator controls the bridge during the last part of its movement by looking at images recorded by the video cameras. Suggestions are made in the patent specification that the system could be arranged to operate in a fully automated manner using image-processing of the recorded images to calculate the distance between the passenger loading bridge and the aircraft. However, image-processing is time-consuming, thus making the movement based thereon slow.
WO 96/08411, filed Sep. 14, 1995 in the name of Anderberg, discloses another device for controlling the movement of a passenger loading bridge. When an aircraft has landed, a central computer, such as for instance a central computer located within a terminal building, transmits information on the type or model of aircraft to a local computer of the passenger loading bridge at an assigned gate. The local computer accesses a local database and retrieves information on the positions of the doors for the type of aircraft that has landed, as well as information on the expected stopping position for the type of aircraft at the assigned gate. The retrieved information allows the local computer to determine an absolute position of the door with which the passenger loading bridge is to be aligned. The system also includes sensors for providing real-time positional data for a cab end of the bridge to the local computer. Accordingly, the passenger loading bridge is moved under computer control to a position close to the determined position of the door, for example within 2-10 meters. Optionally, the bridge is preset to this position before the aircraft has stopped moving.
WO 01/34467, filed Nov. 8, 2000 also in the name of Anderberg, teaches that the above system is reliable only for movement to a position close to the aircraft. Thus, the bridge has to be operated manually during the remaining 2-10 meters of its movement. The WO 01/34467 reference also teaches an improvement to the above system, in which electromagnetic sensors are disposed along the distal end of the passenger loading bridge for transmitting a set of electromagnetic pulses in different directions and for detecting electromagnetic pulses after reflection from an aircraft. Based upon the elapsed time between transmitting and detecting the electromagnetic pulses in different directions, a profile of distance as a function of direction is obtained. From the measured distance versus direction profile and the information stored in the computer, it is then possible to maneuver the bridge to the doorway of the aircraft. Unfortunately, the local computer must be in communication with a flight information database of the airport terminal building in order to receive information relating to the type or model of aircraft that is approaching the gate. Such a database must be set up to be accessible by the local computer, and there may be serious security-related issues involved with providing widely distributed access to sensitive flight information. Furthermore, many airports around the world do not support databases that would be suitable for interfacing with a passenger loading bridge system as described by Anderberg. In those cases, the authorities considering an automated passenger bridge would demand a system capable of completely autonomous operation.
Additionally, there are prior art systems for guiding the aircraft to the correct location for docking with a passenger boarding bridge. Fabriksmonteringin Trelleborg AB describe a current state of the art system. The aircraft parking and information system API++™ is a laser-based visual docking guidance system used to visually guide a pilot to intercept and establish an aircraft on a gate centerline, and to proceed to a stopping position at an aircraft gate. Real-time azimuth guidance is provided to the pilot by means of a unique Moiré technology azimuth guidance unit. Aircraft type and series information is displayed on an alphanumeric display panel, confirming to the pilot to proceed with the docking maneuver. Aircraft closing rate and stopping position information is provided by a closing rate indicator, which starts a distance-to-go countdown when the aircraft is within close range from its correct stopping position. When interfaced to flight information display systems (FIDS), airports operations database control (AODC) or to air traffic control center (ATCC), APIS++™ receives notification that an aircraft has landed. Further provided to the APIS++™ is an automatic selection of aircraft type. Advantageously, APIS++™ communicates and cooperates with passenger boarding bridges during the process of docking the aircraft. A similar system is described in detail in U.S. Pat. No. 6,324,489, issued to Millgard, filed 29 Oct. 1999. This system, like the APIS++™, provides visual cues to the pilot of an aircraft to assist the pilot in correctly positioning the aircraft relative to the terminal building. The system according to Millgard also makes use of a laser mounted to a stationary fixture to identify and determine the position of the aircraft.
It is a disadvantage of the prior art manual, semi-automated and automated bridge alignment systems that the alignment operation is performed on the basis of observations that are made from a location that is remote to the aircraft. If such observations are erroneous, then the bridge may be allowed to collide unintentionally with the aircraft. Examples of observations that are prone to error include: visually or electronically determining a type of the aircraft; keying in a type of the aircraft into a flight information database; judging the distance remaining between the bridge and the aircraft, etc. Of course, adverse environmental conditions, such as snow, fog, darkness, etc., will greatly increase the likelihood of an erroneous observation.
It would be advantageous to provide a system that simplifies the approach of the aircraft and the docking of the passenger boarding bridge beyond the advances described with reference to the prior art. Further, it would be beneficial to provide members of the flight crew aboard the aircraft some control over the passenger boarding bridge.
SUMMARY OF EMBODIMENTS OF THE INVENTION According to an aspect of the instant invention, there is provided a system for aligning one end of a passenger loading bridge to an aircraft having a doorway, the doorway defined within a side-wall of the aircraft, the side-wall including an inner wall defining an interior surface of the side-wall and an outer wall defining an exterior surface of the side-wall, the inner wall and the outer wall disposed in a spaced-apart arrangement one relative to the other, so as to define at least a space therebetween, the system comprising: a transmitter disposed within the at least a space of the side-wall for providing an electromagnetic signal for use during an operation for aligning the one end of the passenger loading bridge to the doorway of the aircraft; a receiver disposed about a point having a known location relative to the one end of the passenger loading bridge, for receiving the electromagnetic signal transmitted from the transmitter, and for providing an electrical output signal relating to the electromagnetic signal; a bridge controller in electrical communication with the receiver, for receiving the electrical output signal provided from the receiver, for determining a next movement of the one end of the passenger loading bridge in a direction toward the doorway of the aircraft based upon the electrical output signal, and for providing a control signal relating to the determined next movement; and, a drive mechanism in communication with the bridge controller, for receiving the control signal therefrom, and for driving the one end of the passenger loading bridge in the determined direction toward the doorway of the aircraft.
According to another aspect of the instant invention there is provided a kit for retrofitting an aircraft, the aircraft having a space contained within a side-wall thereof, the side-wall including an interior wall defining an interior surface of the side-wall and an outer wall defining an exterior surface of the side-wall, the kit comprising: a transmitter module for being fixedly mounted within the space between the interior wall and the exterior wall and for transmitting an electromagnetic signal within a predetermined region of the electromagnetic spectrum; and, a mount for securing the transmitter within the space.
According to yet another aspect of the instant invention there is provided a method of retrofitting an aircraft having a doorway, the aircraft having a space contained within a side-wall thereof, the side-wall including an interior wall defining an interior surface of the side-wall and an outer wall defining an exterior surface of the side-wall, the method comprising: providing an opening in the exterior surface of the side-wall at a point proximate the doorway, the opening sized for accepting a housing; mounting a housing within the opening; securing a transmitter module to the housing; providing an electrical connection between the transmitter module and an on-board power system of the aircraft; and, securing a cover adjacent to the opening, so as to provide a surface that is substantially continuous with the exterior surface of the side-wall.
According to still another aspect of the instant invention there is provided an apparatus for aligning one end of a passenger loading bridge to an aircraft having a doorway, the doorway defined within a side-wall of the aircraft, the side-wall including an interior wall defining an interior surface of the side-wall and an outer wall defining an exterior surface of the side-wall, the aircraft having a space contained within the side-wall, the apparatus comprising: a mounting structure; and, a transmitter for being fixedly mounted, via the mounting structure, at a location within the space between the interior wall and the exterior wall, the transmitter for wirelessly providing a signal within a predetermined region of the electromagnetic spectrum, the signal comprising information relating to a location of the doorway relative to the location of the transmitter.
According to still another aspect of the instant invention there is provided a system for aligning an aircraft-engaging end of a passenger boarding bridge to a doorway that is disposed along a lateral surface of an aircraft, comprising: a bridge controller for aligning automatically the aircraft-engaging end of the passenger boarding bridge to the doorway; a control module disposed aboard the aircraft for receiving from a user aboard the aircraft an input signal that is indicative of an emergency stop request; a first transmitter disposed aboard the aircraft and in communication with the control module, the first transmitter for receiving from the control module a signal relating to the emergency stop request and for transmitting a control signal in dependence thereon; and, a first receiver disposed at a location that is remote from the aircraft, the first receiver in communication with the bridge controller for receiving the transmitted control signal and for automatically providing the transmitted control signal to the bridge controller.
According to still another aspect of the instant invention there is provided a method of aligning an aircraft-engaging end of a passenger boarding bridge to a doorway that is disposed along a lateral surface of an aircraft, the method comprising: initiating an automated alignment process for aligning the aircraft-engaging end of the passenger boarding bridge to the doorway that disposed along the lateral surface of the aircraft; receiving from a user aboard the aircraft an input signal that is indicative of an emergency stop request; transmitting a control signal relating to the input signal using a transmitter that is disposed aboard the aircraft; receiving the control signal at a location that is remote from the aircraft; providing the control signal to a bridge controller of the passenger boarding bridge; and, stopping the automated alignment process currently in progress in response to receiving the control signal at the bridge controller.
BRIEF DESCRIPTION OF THE DRAWINGS Exemplary embodiments of the invention will now be described in conjunction with the following drawings, in which similar reference numbers designate similar items:
FIG. 1 is a top plan view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a first embodiment of the instant invention;
FIG. 2ais a schematic block diagram of a transmitter unit for use with the system illustrated inFIG. 1;
FIG. 2bis a schematic block diagram of a receiver unit for use with the system illustrated inFIG. 1;
FIG. 3 is a top plan view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a second embodiment of the instant invention;
FIG. 4ais a schematic block diagram of a transmitter unit for use with the system illustrated inFIG. 3;
FIG. 4bis a schematic block diagram of a receiver unit for use with the system illustrated inFIG. 3;
FIG. 5 is a simplified flow diagram of a method of aligning a passenger boarding bridge to a doorway of an aircraft using the system described with reference toFIG. 1;
FIG. 6 is a simplified flow diagram of another method of aligning a passenger boarding bridge to a doorway of an aircraft using the system ofFIG. 1;
FIG. 7 is a top plan view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a third embodiment of the instant invention;
FIG. 8ais a schematic block diagram of a transceiver unit for use with the system illustrated inFIG. 7;
FIG. 8bis a schematic block diagram of a transceiver unit for use with the system illustrated inFIG. 7;
FIG. 9ais a schematic block diagram of another transceiver unit for use with the system illustrated inFIG. 7;
FIG. 9bis a schematic block diagram of another transceiver unit for use with the system illustrated inFIG. 7;
FIG. 10 is a simplified flow diagram of a method of aligning a passenger boarding bridge to a doorway of an aircraft using the system described with reference toFIG. 7;
FIG. 11 is a simplified flow diagram of another method of aligning a passenger boarding bridge to a doorway of an aircraft using the system ofFIG. 7;
FIG. 12 is a simplified data flow diagram illustrating the sequence of steps involved in confirming a type of the aircraft using the system described with reference toFIG. 7;
FIG. 13 is a schematic top view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a fourth embodiment of the instant invention;
FIG. 14 is a schematic top view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a fifth embodiment of the instant invention;
FIG. 15 is a schematic top view of a passenger boarding bridge and an aircraft equipped with an automated docking system according to a sixth embodiment of the instant invention;
FIG. 16ais a simplified side view showing a first method of aligning a passenger boarding bridge to an aircraft doorway, prior to alignment;
FIG. 16bis a simplified side view showing a first method of aligning a passenger boarding bridge to an aircraft doorway, in which the passenger boarding bridge and the aircraft doorway are aligned;
FIG. 17ais a simplified diagram showing a second method of aligning a passenger boarding bridge to an aircraft doorway, prior to alignment;
FIG. 17bis a simplified diagram showing a second method of aligning a passenger boarding bridge to an aircraft doorway, in which the passenger boarding bridge and the aircraft doorway are aligned;
FIG. 18 is a simplified diagram showing a first triangulation method for aligning a passenger boarding bridge to an aircraft doorway;
FIG. 19ais a simplified diagram showing a second triangulation method for aligning a passenger boarding bridge to an aircraft doorway, prior to alignment;
FIG. 19bis a simplified diagram showing a second triangulation method for aligning a passenger boarding bridge to an aircraft doorway, in which the passenger boarding bridge and the aircraft doorway are aligned;
FIG. 20 is a flow diagram of a method of confirming the authenticity of a “call” signal received by a passenger boarding bridge based transceiver unit, according to yet another embodiment of the instant invention;
FIG. 21 is a top view schematic diagram of a passenger boarding bridge according to an embodiment of the invention docking with an aircraft having a controller for controlling the passenger boarding bridge;
FIG. 22 is a block diagram of method of controlling a passenger boarding bridge remotely;
FIG. 23 is a top view schematic diagram of an aircraft having two doorways, separate passenger boarding bridges are shown in close proximity to the doorways, each of the passenger boarding bridges for being controlled with a controller located on board the aircraft; and,
FIG. 24 is a top view schematic diagram of an aircraft having a transceiver mounted according to a ninth embodiment of the instant invention, docking with a passenger boarding bridge;
FIG. 25 is a simplified view of a typical aircraft door, as viewed from a point exterior to the aircraft;
FIG. 26ais a simplified view of a typical aircraft door, as viewed from a point exterior to the aircraft, and including a transceiver mounted according to the ninth embodiment of the instant invention;
FIG. 26bis a side cross sectional view showing the transceiver ofFIG. 26amounted according to the ninth embodiment of the instant invention;
FIG. 27 is a side cross sectional view showing a transceiver mounted according to a tenth embodiment of the instant invention; and,
FIG. 28 is a side cross sectional view showing a transceiver mounted according to an eleventh embodiment of the instant invention.
DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION The following description is presented to enable a person skilled in the art to make and use the invention, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments and applications without departing from the spirit and the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments disclosed, but is to be accorded the widest scope consistent with the principles and features disclosed herein. Throughout the disclosure and in the claims that follow, it is to be understood that an optical signal includes any signal that is transmitted using one of infrared, visible and ultraviolet radiation.
Referring toFIG. 1, shown is a system according to a first embodiment of the instant invention. Anaircraft21 having adoorway20 is equipped with atransmitter unit29 for transmitting one of an optical signal and a radio frequency (rf) signal. Preferably, thetransmitter unit29 is disposed within a window (not shown) of thedoorway20 to which apassenger boarding bridge1 is to be connected.
Also illustrated inFIG. 1 is thepassenger boarding bridge1, for instance an apron drive bridge including arotunda2 that is connected to aterminal building3 and from which extends apassageway4. Thepassageway4 ends with apivotable cabin5 and includesinner passageway element16 andouter passageway element17, wherein theinner passageway element16 is telescopically received within theouter passageway element17 such that the length of thepassageway4 is variable. Eachpassageway element16,17 includes a left sidewall, a right sidewall, a floor member and a ceiling member. Optionally, a number of passageway elements other than two is provided.
Thepassageway4 is supported by aframe6 for adjusting the height of thepassenger boarding bridge1. Preferably, theframe6 includes a bogie (not shown) with driving wheels (not shown) for achieving angular displacement of thepassenger boarding bridge1 as well as telescoping of thepassageway elements16 and17 to alter the length of thepassageway4. Finally, thepassenger boarding bridge1 includes additional mechanisms (not shown) for pivoting thecabin5 and for leveling a not illustrated floor surface thereof.
Advantageously, the modular design of thepassenger boarding bridge1 allows the bridge to be guided to different positions in order to service a wide range of aircraft models, and/or a wide range of aircraft doorway positions on either the right or left side of theaircraft21. To this end abridge controller7 is provided in communication with the various mechanisms, for providing control signals for automatically adjusting the position of thepassenger boarding bridge1, so as to permit a cabin end of thepassenger boarding bridge1 to be aligned with thedoorway20 of theaircraft21 in an automated manner. Acontrol panel8 is disposed within thecabin5 to be used by a bridge-operator when manual operation is required. Optionally, thecontrol panel8 is located on the opposite side of the cabin.
Thepassenger boarding bridge1 is equipped with first, second andthird transducers10,11 and12 for determining the angular position of the passageway, the height of the passageway and the relative positions of the passageway elements, respectively. Thebridge1 is further equipped with afourth transducer13 for sensing the angular position of thecabin5. Optionally, thesecond transducer11 is disposed proximate theframe6 for determining the height of the passageway. The transducers are in communication with thebridge controller7 and provide control signals thereto, for use by thebridge controller7 in determining a next movement of thepassenger boarding bridge1 toward thedoorway20 of theaircraft21. Of course, other types of transducers and/or other numbers of transducers and/or other locations of transducers are optionally used to determine the position of the bridge. For instance, a laser may be mounted on the roof of thecabin5, as may at least two reflectors on different locations on the terminal building. By sweeping the laser, measuring the distance to the reflectors with the aid of the laser, and determining the angular position of the laser when directed toward the reflectors, the position of thecabin5 is determinable.
Preferably, thepassenger boarding bridge1 further includes arange measuring device14, for instance an electromagnetic distance meter, for sensing a close approach of the passenger boarding bridge to theaircraft21. An electromagnetic signal used for determining the distance to the aircraft by the distance meter is optionally an optical signal with a fixed wavelength range within the infrared spectrum. Alternatively, the range measuring device is acoustic. Further optionally, therange measuring device14 provides a signal to thebridge controller7 for automatically reducing the rate of approach of thepassenger boarding bridge1 to theaircraft21 within a predetermined distance. Further optionally, one ormore pressure sensors15 are provided along a bumper at the cabin end of thepassenger boarding bridge1 for sensing engagement with theaircraft21. Of course, therange measuring device14 and the one ormore pressure sensors15 are effective only at very close approach to theaircraft21.
Referring still toFIG. 1, thepassenger boarding bridge1 includes at least areceiver unit23 fixedly mounted near the cabin end of thepassenger boarding bridge1, for receiving the one of an optical signal and a radio frequency (rf) signal emitted bytransmitter unit29 of theaircraft21. Optionally, a second receiver (not shown) is disposed along one of the outside lateral surfaces of thepassenger boarding bridge1 for receiving the one of an optical signal and a radio frequency (rf) signal emitted bytransmitter unit29 of theaircraft21 when the passenger boarding bridge is in a stowed position. The signal is emitted by thetransmitter unit29 of theaircraft21 to “call” for thepassenger boarding bridge1 when theaircraft21 is parked at the gate area adjacent thepassenger boarding bridge1. Preferably, the signal is also used to guide the cabin end of thepassenger boarding bridge1 into engagement with thedoorway20 of theaircraft21. When the signal is in the form of an optical signal, for instance an infrared signal, an optional shroud (not shown) is provided to shield the emitters and detectors and to provide beam-angle restriction. This is to ensure precise alignment and zone detection for docking and also to minimize interference from other light sources. Suitable shrouds having a plastic or metal housing are known in the art.
Referring now toFIG. 2a, atransmitter unit29 for use with a first embodiment of the instant invention is shown in greater detail. Thetransmitter unit29 includes awireless transmitter70, for instance one of an optical transmitter and a radio frequency (rf) transmitter, and anonboard power source71, such as for instance a rechargeable battery pack. Thetransmitter unit29 includes asignal generator72 in communication with thewireless transmitter70, for generating the signal to be transmitted by thewireless transmitter70.
Referring now toFIG. 2b, areceiver unit23 for use with the first embodiment of the instant invention is shown in greater detail. Elements labeled with the same numerals have the same function as those illustrated inFIG. 2a. Thereceiver unit23 includes awireless receiver73 for receiving the signal transmitted by thetransmitter unit29. Thewireless receiver73 is in communication with a data input/output port74 for providing the received signal to thebridge controller7 of thepassenger boarding bridge1.
Referring again toFIG. 1, the illustrated system is for use with passive methods of alignment in which one-way communication occurs between theaircraft21 and thepassenger boarding bridge1. In a first mode of operation of the system shown inFIG. 1, every type of aircraft emits a generic signal, which is a same signal for every type of aircraft. In use, thetransmitter unit29 emits the generic signal, which is received by thereceiver unit23. Thereceiver unit23 provides the generic signal to thebridge controller7. Thebridge controller7 uses the generic signal to align the cabin end of thepassenger boarding bridge1 with thedoorway20 of theaircraft21. For example, the bridge controller actuates mechanisms of the passenger boarding bridge, so as to move the cabin end of the passenger boarding bridge into a position in which thereceiver unit23 is precisely aligned with thetransmitter unit29. To this end, thetransmitter unit29 is preferably positioned at a same predetermined location relative to the outline of thedoorway20 for every type ofaircraft21, such that thepassenger boarding bridge1 is reliably aligned to the doorway whenever thetransmitter unit29 and thereceiver unit23 are precisely aligned. Suitable methods for aligning thereceiver unit23 with thetransmitter unit29 are discussed in greater detail, below.
In a second mode of operation of the system shown inFIG. 1, each different class of aircraft is assigned a class-specific signal, for instance the signal for a 737-700 is different from the signal for a 737-800 which is different from the signal for a 747-400 and so on. To this end, thetransmitter unit29 is configured to transmit the class-specific signal corresponding to the type of theaircraft21. In use, thetransmitter unit29 emits the class-specific signal, which is received by thereceiver unit23. The class-specific signal is provided to thebridge controller7 and analyzed to determine information pertaining to certain attributes of the aircraft, such as for instance doorway height, front and rear doorway separation, expected stopping position of the type of aircraft, etc. Optionally, thebridge controller7 uses the class-specific information to pre-set thepassenger boarding bridge1 to a predetermined position, in advance of theaircraft21 coming to a complete stop.
It is an advantage of the present embodiment of the instant invention that an authorized user may reconfigure thetransmitter unit29, so as to change the class specific signal that is emitted, in order to accommodate a different class of aircraft. Accordingly, one type oftransmitter unit29 can be manufactured and subsequently configured by an authorized user to represent a desired class of aircraft. Furthermore, if an aircraft type is retired or otherwise changed, then thetransmitter unit29 can be salvaged and reconfigured for use with a different type of aircraft. Preferably, the reconfiguration of thetransmitter unit29 requires correct authorization, in order to ensure safe operation of the system. Further advantageously, thetransmitter unit29 supports use with a large plurality of types of aircraft. For example, using a simple 8 bit-encoding scheme, it is possible to represent 256 different types of aircraft.
Referring toFIG. 3, shown is a system according to a second embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 1. Anaircraft21 having adoorway20 is equipped with atransmitter unit39 for transmitting one of an optical signal and a radio frequency (rf) signal. Preferably, thetransmitter unit39 is disposed within a window (not shown) of thedoorway20 to which apassenger boarding bridge1 is to be connected. Thepassenger boarding bridge1 includes areceiver unit33 fixedly mounted near the cabin end of thepassenger boarding bridge1, for receiving the one of an optical signal and a radio frequency (rf) signal emitted bytransmitter unit39 of theaircraft21. The signal is emitted by thetransmitter unit39 of theaircraft21 to “call” for thepassenger boarding bridge1 when theaircraft21 is parked at the gate area adjacent thepassenger boarding bridge1. Preferably, the signal is also used to guide the cabin end of thepassenger boarding bridge1 into engagement with thedoorway20 of theaircraft21. When the signal is in the form of an optical signal, for instance an infrared signal, an optional shroud (not shown) is provided to shield the emitters and detectors and to provide beam-angle restriction. This is to ensure precise alignment and zone detection for docking and also to minimize interference from other light sources. Suitable shrouds having a plastic or metal housing are known in the art. A signal provided by the transmitter unit indicates the position of the transmitter unit relative to the doorway. In this way, the transmitter unit need not be provided in a window of a doorway of the aircraft. Clearly, if it is desirable to support a wide range of mounting locations for thetransmitter unit39, then thereceiver unit33 should support all of these mounting locations. In order to support a wide range oftransmitter unit39 locations thereceiver unit33 is optionally an array of receiver units, each for supporting the reception of signals provided by atransmitter unit39 disposed within a predetermined portion of the supported transmitter unit mounting locations. For example, if thetransmitter unit39 is positioned in a window of a doorway of the aircraft then a first receiver of the passenger boarding bridge is used to receive the signal. If thetransmitter unit39 is instead positioned in a window of the cockpit of the aircraft then a second receiver unit is used. Similarly, if thetransmitter unit39 is positioned at the top of the fuselage of the aircraft then a third receiver is used. Clearly, the nature of the signal being transmitted from thetransmitter unit39 and the desired alignment accuracy will determine the appropriate number and position of the receivers.
Referring now toFIG. 4a, shown is atransmitter unit39 for use with the second embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 2a. Thetransmitter unit39 includes awireless transmitter70, for instance one of an optical transmitter and a radio frequency (rf) transmitter, in communication with aprocessor75. Theprocessor75 is further in communication with each one of amemory circuit76, adata entry device77 and a data input/output port78. Thetransmitter unit39 includes anonboard power source71 such as for instance a rechargeable battery pack coupled to an onboard power system of theaircraft21 via apower coupling79. Thedata entry device77 is for use by a flight-crew member for providing ancillary information to be transmitted by thetransmitter unit39. The processor also stores within thememory circuit76 any data that is provided from the aircraft central computer system (not shown) via data input/output port78. During use, the processor generates a signal including data retrieved from thememory circuit76, and provides the signal to thewireless transmitter70 for transmission thereby.
Referring now toFIG. 4b, shown is areceiver unit33 for use with the second embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 2b. Thereceiver unit33 includes awireless receiver73 for receiving the signal transmitted by the transmittingunit39. Thewireless receiver73 is also in communication with each one of amemory circuit80 for retrievably storing information relating to the bridge alignment process, and a data input/output port74 for transferring the received signal to thebridge controller7 of thepassenger boarding bridge1.
Referring again toFIG. 3, the illustrated system is for use with passive methods of alignment in which one-way communication occurs between theaircraft21 and thepassenger boarding bridge1. In a first mode of operation of the system shown inFIG. 3, every type of aircraft uses a generic signal, which is a same signal for every type of aircraft. In use, thetransmitter unit39 emits the generic signal, which is received by thereceiver unit33. Thereceiver unit33 provides the generic signal to thebridge controller7 via the data input/output port74. Thebridge controller7 uses the generic signal to align the cabin end of thepassenger boarding bridge1 with thedoorway20 of theaircraft21. For example, the bridge controller actuates mechanisms of the passenger boarding bridge, so as to move the cabin end of the passenger boarding bridge into a position in which thereceiver unit33 is precisely aligned with thetransmitter unit39. To this end, thetransmitter unit39 is preferably positioned at a same predetermined location relative to the outline of thedoorway20 for every type ofaircraft21, such that thepassenger boarding bridge1 is reliably aligned to the doorway whenever thetransmitter unit39 and thereceiver unit33 are precisely aligned. Suitable methods for aligning thereceiver unit33 with thetransmitter unit39 are discussed in greater detail, below.
In a second mode of operation of the system shown inFIG. 3, every class of aircraft is assigned a class-specific signal, for instance the signal for a 737-700 is different from the signal for a 737-800 which is different from the signal for a 747-400 and so on. In use, thetransmitter unit39 emits the class-specific signal, which is received by thereceiver unit33. The class-specific signal is provided to thebridge controller7 via the data input/output port74, and is analyzed to determine information pertaining to certain attributes of the aircraft, such as for instance doorway height, front and rear doorway separation etc. Optionally, thebridge controller7 uses the class-specific information to pre-set thepassenger boarding bridge1 to a predetermined position, in advance of theaircraft21 coming to a complete stop.
Further optionally, the signal transmitted by thewireless transmitter70 includes ancillary data provided by a flight-crew member using thedata entry device77 of thetransmitter unit39. For example, the flight-crew member provides the number of passengers on board theaircraft21 using thedata entry device77, and theprocessor75 stores the ancillary information within thememory circuit76. When theaircraft21 approaches the passenger boarding bridge, thetransmitter unit39 provides the ancillary information to thebridge controller7 via thereceiver unit33. Thebridge controller7 then uses the ancillary information to determine whether or not the use of a second bridge, for example an over the wing passenger boarding bridge, when available, is desired.
Furthermore, the ancillary information transmitted from the aircraft based transmitter unit to the passenger boarding bridge can be used in an automated airport billing system, wherein an airline is billed according to the number of seats and/or the number of passengers aboard each flight that is serviced by the passenger boarding bridge. Of course, the ancillary information may also relate to, for instance, a sensed internal cabin temperature of the aircraft. In the latter case, the ancillary information is used to control a preconditioned air unit for maintaining the internal cabin temperature of the aircraft within a predetermined range of values. In this way, aircraft that are parked for long periods of time or even over night in a cold climate may be reliably heated at a constant temperature so as to prevent freezing, and in a secure manner that does not require one of the doorways to be left unsecured so as to introduce a wired temperature sensor into the interior cabin of the aircraft.
Referring now toFIG. 5, shown is a method of aligning thepassenger boarding bridge1 with thedoorway20 of theaircraft21 using the system ofFIG. 3. Thetransmitter unit39 transmits a generic “call” signal to thereceiver unit33. Thereceiver unit33 provides the generic “call” signal to thebridge controller7. In dependence upon receiving the generic “call” signal, thebridge controller7 “wakes up” from a standby mode and enters an alignment mode of operation. Thebridge controller7 adjusts the vertical and horizontal position of the passenger boarding bridge such that thereceiver unit33 becomes precisely aligned with or “homes in on” thetransmitter unit39. Preferably, thebridge controller7 enters a service mode of operation once the alignment operation is complete. The service mode of operation includes functions such as auto-leveling thepassenger boarding bridge1 during the enplaning and/or deplaning operations, etc.
Optionally, thebridge controller7 receives other signals from therange measuring device14 and the one ormore pressure sensors15, such that the rate of approach of thepassenger boarding bridge1 to theaircraft21 is optionally automatically reduced as the distance to theaircraft21 decreases.
Referring now toFIG. 6, shown is another method of aligning thepassenger boarding bridge1 with thedoorway20 of theaircraft21 using the system ofFIG. 3. Thetransmitter unit39 transmits a class-specific “call” signal to thereceiver unit33, wherein the class-specific “call” signal includes information relating to certain attributes of the aircraft, such as for instance doorway height, front and rear doorway separation, expected stopping position etc. Thereceiver unit33 provides the class-specific “call” signal to thebridge controller7. In dependence upon receiving the class-specific “call” signal, thebridge controller7 “wakes up” from a standby mode and enters an alignment mode of operation. Thebridge controller7 analyzes the class-specific “call” signal to extract the information pertaining to certain attributes of the aircraft. Based on the extracted information, thebridge controller7 optionally pre-sets the passenger boarding bridge to a position close to the expected stopping position of thedoorway21 of theaircraft20. The final adjustments to align thepassenger boarding bridge1 to thedoorway21 of theaircraft20 are performed by “homing in on” the class-specific “call” signal being transmitted by thetransmitter unit39. Thepassenger boarding bridge1 is aligned when the vertical and horizontal position of the passenger boarding bridge is such that thereceiver unit33 is precisely aligned with thetransmitter unit39. Preferably, thebridge controller7 enters a service mode of operation once the alignment operation is complete. The service mode of operation includes functions such as auto-leveling thepassenger boarding bridge1 during the enplaning and/or deplaning operations, etc.
Optionally, thebridge controller7 receives other signals from therange measuring device14 and the one ormore pressure sensors15, such that the rate of approach of thepassenger boarding bridge1 to theaircraft21 is optionally automatically reduced as the distance to theaircraft21 decreases.
Of course, the methods described with reference toFIGS. 5 and 6 are also applicable to the system described with reference toFIG. 1.
It is an advantage of the second embodiment of the instant invention that an authorized user may reconfigure thetransmitter unit39, so as to change the class specific signal that is emitted, in order to accommodate a different class of aircraft. Accordingly, one type oftransmitter unit39 can be manufactured and subsequently configured by an authorized user to represent a desired class of aircraft. Furthermore, if an aircraft type is retired or otherwise changed, then thetransmitter unit39 can be salvaged and reconfigured for use with a different type of aircraft. Of course, the reconfiguration of thetransmitter unit39 requires correct authorization, in order to ensure safe operation of the system. Further advantageously, thetransmitter unit39 supports use with a large plurality of types of aircraft. For example, using a simple 8 bit-encoding scheme, it is possible to represent 256 different types of aircraft.
Referring now toFIG. 7, shown is a system according to a third embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 1.Aircraft21 includes atransceiver22 for transmitting one of an optical signal and an RF signal and for receiving one of an optical signal and an RF signal. Preferably, thetransceiver22 is disposed within a window (not shown) of thedoorway20 to which apassenger boarding bridge1 is to be connected. Thetransceiver22 is used only during the aircraft docking and passenger boarding bridge alignment operations.Passenger boarding bridge1 includes atransceiver24, for receiving the one of an optical signal and an RF signal transmitted from theaircraft21 and for transmitting the one of an optical signal and an RF signal to be received by thetransceiver22 ofaircraft21. Accordingly, two-way communication occurs between theaircraft21 and thepassenger boarding bridge1, which permits the implementation of active methods of alignment.
Referring now toFIG. 8a, shown is atransceiver22 for use with the third embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 4a.Transceiver22 additionally includes areceiver90 in communication with theprocessor75, and adisplay device92 also in communication with theprocessor75. For instance, thedisplay device92 is one of an LCD screen, an LED display and a speaker. Thedisplay device92 is positioned for providing a human sensible indication to a member of the flight-crew on board theaircraft21. Thereceiver90 is for receiving signals from thepassenger boarding bridge1, and for providing said signals to theprocessor75. For example, thereceiver90 is for receiving an alignment complete signal, which is provided to theprocessor75. Theprocessor75, in use, provides a control signal to thedisplay device92 for indicating to the member of the flight-crew that the alignment operation is complete and that it is safe to open thedoorway20.
Referring now toFIG. 8b, shown is atransceiver24 for use with the third embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 4b.Transceiver24 additionally includes atransmitter91 in communication with the data input/output port74 and with thememory circuit80. Thetransmitter91 is for receiving data from thebridge controller7 via the data input/output port74 and/or the memory circuit, and for transmitting said received data to theaircraft21.
Referring again toFIG. 7, the illustrated system is for use with active methods of alignment in which two-way communication occurs between theaircraft21 and thepassenger boarding bridge1. In a first mode of operation of the system shown inFIG. 7, every type of aircraft uses a generic signal, which is a same signal for every type of aircraft. In use, thetransceiver22 emits the generic signal, which is received by thetransceiver24. Thetransceiver24 provides the generic signal to thebridge controller7. Thebridge controller7 uses the generic signal to align the cabin end of thepassenger boarding bridge1 with thedoorway20 of theaircraft21. For example, the bridge controller actuates mechanisms of the passenger boarding bridge, so as to move the cabin end of the passenger boarding bridge into a position in which thetransceiver24 is precisely aligned with thetransceiver22. To this end, thetransceiver22 is preferably positioned at a same predetermined location relative to the outline of thedoorway20 for every type ofaircraft21, such that thepassenger boarding bridge1 is reliably aligned to the doorway whenever thetransceiver22 and thetransceiver24 are precisely aligned. Suitable methods for aligning thetransceiver22 with thetransceiver24 are discussed in greater detail, below.
In a second mode of operation of the system shown inFIG. 7, each different class of aircraft is assigned a class-specific signal, for instance the signal for a 737-700 is different from the signal for a 737-800 which is different from the signal for a 747-400 and so on. To this end, thetransceiver22 is configured to transmit the class-specific signal corresponding to the type of theaircraft21. In use, thetransceiver22 emits the class-specific signal, which is received by thetransceiver22. The class-specific signal is provided to thebridge controller7 and analyzed to determine information pertaining to certain attributes of the aircraft, such as for instance doorway height, front and rear doorway separation, expected stopping position of the type of aircraft, etc. Optionally, thebridge controller7 uses the class-specific information to pre-set thepassenger boarding bridge1 to a predetermined position, in advance of theaircraft21 coming to a complete stop.
Referring again toFIG. 8a, thetransceiver22 is in communication with adata entry device77, for instance one of an alphanumeric keypad and an iconic keypad, for allowing a member of the flight-crew to enter ancillary information, such as for instance a number of passengers aboard theaircraft21, to be transmitted by thetransceiver22. Advantageously, thebridge controller7 can determine automatically whether or not the use of a second bridge, for example an over-the-wing bridge, when available, is desired based upon the number of passengers aboard theaircraft21.
Referring now toFIG. 9a, shown is another transceiver for use with the third embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 2a.Transceiver93 additionally includes areceiver90 and adisplay device92 also in communication with theprocessor75. For instance, thedisplay device92 is in the form of one of an LCD screen, an LED display and a speaker. Thereceiver90 is for receiving signals from thepassenger boarding bridge1, and for providing said signals to theprocessor75. For example, thereceiver90 is for receiving an alignment complete signal, which is provided to theprocessor75. Theprocessor75, in use, provides a control signal to thedisplay device92 for indicating to a member of the flight-crew that the alignment operation is complete and that it is safe to open thedoorway20.
Referring now toFIG. 9b, shown is another transceiver for use with the third embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 2b.Transceiver94 additionally includes atransmitter91 in communication with the data input/output port74. Thetransmitter91 is for receiving data from thebridge controller7 via the data input/output port74 and for transmitting said data to theaircraft21. For example, thetransmitter91 is for transmitting the alignment complete signal after thepassenger boarding bridge1 is aligned with thedoorway20 of theaircraft21.
Referring now toFIG. 10, shown is a method of aligning thepassenger boarding bridge1 with thedoorway20 of theaircraft21 using the system illustrated inFIG. 7. The method is described with specific reference totransceivers22 and24, however, the method is equally applicable whentransceiver93 replacestransceiver22 and/ortransceiver94 replacestransceiver24. Thetransceiver22 transmits a generic “call” signal to thetransceiver24. Thetransceiver24 provides the generic “call” signal to thebridge controller7. In dependence upon receiving the generic “call” signal, thebridge controller7 “wakes up” from a standby mode and enters an alignment mode of operation. Thebridge controller7 adjusts the vertical and horizontal position of the passenger boarding bridge such that thetransceiver24 becomes precisely aligned with thetransceiver22. After making final adjustments to thepassenger boarding bridge1 position, the bridge controller usestransceiver24 to emit an alignment confirmation request signal totransceiver22 aboard theaircraft21. If thetransceiver22 returns a confirmation signal, then the alignment operation is complete, and thebridge controller7 preferably enters a service mode of operation. The service mode of operation includes functions such as auto-leveling thepassenger boarding bridge1 during the enplaning and/or deplaning operations, etc. If thetransceiver22 returns an “alignment incomplete” signal, then the bridge controller further adjusts the position of thepassenger boarding bridge1, and re-sends the alignment confirmation request signal. Preferably, after a predetermined number of failed alignment attempts, the bridge controller automatically transmits a signal for requesting manual bridge alignment.
Optionally, thebridge controller7 receives other signals from therange measuring device14 and the one ormore pressure sensors15, such that the rate of approach of thepassenger boarding bridge1 to theaircraft21 is optionally automatically reduced as the distance to theaircraft21 decreases.
Referring now toFIG. 11, shown is another method of aligning thepassenger boarding bridge1 with thedoorway20 of theaircraft21 using the system illustrated inFIG. 7. The method is described with specific reference totransceivers22 and24, however, the method is equally applicable whentransceiver93 replacestransceiver22 and/ortransceiver94 replacestransceiver24. Thetransceiver22 transmits a class-specific “call” signal to thetransceiver24, wherein the class-specific “call” signal includes information relating to certain attributes of the aircraft, such as for instance doorway height, front and rear doorway separation, expected stopping position etc. Thetransceiver24 provides the class-specific “call” signal to thebridge controller7. In dependence upon receiving the class-specific “call” signal, thebridge controller7 “wakes up” from a standby mode and enters an alignment mode of operation. Thebridge controller7 analyzes the class-specific “call” signal to extract the information pertaining to certain attributes of the aircraft. Based on the extracted information, thebridge controller7 pre-sets the passenger boarding bridge to a position close to the expected stopping position of thedoorway21 of theaircraft20. The final adjustments to align thepassenger boarding bridge1 to thedoorway21 of theaircraft20 are performed by “homing in” on the class-specific “call” signal being transmitted by thetransceiver22. Thepassenger boarding bridge1 is aligned when the vertical and horizontal position of the passenger boarding bridge is such that thetransceiver24 is precisely aligned with thetransceiver22. After making final adjustments to thepassenger boarding bridge1 position, the bridge controller usestransceiver24 to emit an alignment confirmation request signal totransceiver22 aboard theaircraft21. If thetransceiver22 returns a confirmation signal, then the alignment operation is complete, and thebridge controller7 preferably enters a service mode of operation. The service mode of operation includes functions such as auto-leveling thepassenger boarding bridge1 during the enplaning and/or deplaning operations, etc. If thetransceiver22 returns an “alignment incomplete” signal, then the bridge controller further adjusts the position of thepassenger boarding bridge1, and re-sends the alignment confirmation request signal. Preferably, after a predetermined number of failed alignment attempts, the bridge controller automatically transmits a signal for requesting manual bridge alignment.
Optionally, thebridge controller7 receives other signals from therange measuring device14 and the one ormore pressure sensors15, such that the rate of approach of thepassenger boarding bridge1 to theaircraft21 is optionally automatically reduced as the distance to theaircraft21 decreases.
Still further optionally, enhanced two-way communication is provided between theaircraft21 and thepassenger boarding bridge1, such that every signal that thetransceiver22 emits is confirmed by thetransceiver24.FIG. 12 shows simplified flow diagram of a preferred two-way communications scheme, using the specific and non-limiting example of confirming the class of the aircraft. Thetransceiver22 ofaircraft21 emits a signal for a 737-800, which is received by thetransceiver24 of thepassenger boarding bridge1.Transceiver24 receives the signal, recognizes theaircraft21 as a 737-900, and emits a confirmation signal to thetransceiver22 indicating that a 737-900 has been acknowledged.Transceiver22 receives the confirmation signal and recognizes that thetransceiver22 has transmitted an incorrect confirmation signal. Thetransceiver22 ofaircraft21 re-emits a signal for a 737-800, which is received and correctly recognized by thetransceiver24.Transceiver24 emits a confirmation signal to thetransceiver22 indicating that a 737-800 has been acknowledged and requesting confirmation.Transceiver22 emits a confirmation signal, thereby completing the recognition sequence. Of course, a number of steps greater than or less than the number of steps illustrated in the above example may in practice be necessary to successfully complete a two-way communication.
Referring now toFIG. 13, shown is a system according to a fourth embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 7. The system according to the fourth embodiment includes atransceiver22 aboard theaircraft21, atransceiver24 carried near a cabin end ofpassenger boarding bridge1, and a Central Control Unit (CCU)25 including atransceiver26 and adisplay device27. Thetransceivers22,24 and26 are optionally one of an optical transceiver for transmitting and receiving optical signals, and a radio frequency (rf) transceiver for transmitting and receiving RF signals.
In a preferred embodiment, theCCU25 is disposed along an exterior surface of theterminal building3, wherein theCCU25 is in communication with thebridge controller7 of the passenger boarding bridge via a not illustrated communications cable. Optionally, two-way free-space communication occurs between thetransceiver26 of theCCU25 andtransceiver24 of thebridge1. EveryCCU25 is responsible for apassenger boarding bridge1 and for a predetermined section of space adjacent the passenger boarding bridge. Whenever anaircraft21 enters this predetermined section of space, theCCU25 coordinates communication between the approachingaircraft21 and thepassenger boarding bridge1.
In use, thetransceiver22 aboard theaircraft21 transmits a “call” signal as described supra. The “call” signal is received by thetransceiver26 of theCCU25. Preferably, the “call” signal is a class specific “call” signal, which includes data relating to the class of theaircraft21. TheCCU25 also senses positional and trajectory information relating to the approachingaircraft21. To this end, additional not illustrated sensors are disposed on or about theCCU25 for sensing the approach of theaircraft21. Based upon the received “call” signal and the sensed approach information relating to theaircraft21, theCCU25 determines instructions for guiding the approachingaircraft21 to an expected stopping position for the specific class of aircraft. Furthermore, theCCU25 formats the instructions and usesdisplay device27 to display said formatted instructions, so as to provide to the pilot instructions for parking theaircraft21 at an expected stopping position for the type ofaircraft21, in a substantially manual fashion.
Once theaircraft21 is parked, thepassenger boarding bridge1 is aligned with thedoorway20 of theaircraft21. Specifically, theCCU25 transmits signals to the passenger boarding bridge for guiding the cabin end of the bridge toward theaircraft21. The signals include information received from thetransceiver22 and from the not illustrated sensors disposed on or about theCCU25. Thebridge controller7 receives the signals from theCCU25 and uses the received signals in combination with the control signals provided by thebridge transducers10,11,12,13 to align the cabin end of thepassenger boarding bridge1 with thedoorway20 of theaircraft21.
Preferably, the pilot can deactivate the system described with reference toFIG. 13 by activating a master switch (not shown) located aboard theaircraft21, preferably within the flight deck ofaircraft21. When the pilot has deactivated the system, theaircraft21 emits a “not active” signal as it approaches the parking area. In turn, theCCU25 instructs the pilot to stop, and to wait for ground crew to prepare for a manned or a semi-automated docking sequence.
Referring toFIG. 14, shown is a system according to a fifth embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 13. This system allows theaircraft21 to make its final approach to a docking area adjacent thepassenger boarding bridge1 without any assistance from a flight crew or airport ground crew member. The system according to the fifth embodiment includes atransceiver22 aboardaircraft21, atransceiver24 carried near a cabin end ofpassenger boarding bridge1, and a Central Control Unit (CCU)28 including astationary transceiver31. Thestationary transceiver31 is for providing two-way communication between theCCU28 and theaircraft21 via thetransceiver22. Thetransceivers22,24 and31 are optionally one of an optical transceiver for transmitting and receiving optical signals, and a radio frequency (rf) transceiver for transmitting and receiving RF signals.
In a preferred embodiment, theCCU28 is disposed along an exterior surface of theterminal building3, wherein theCCU28 is in communication with thebridge controller7 of the passenger boarding bridge via a not illustrated communications cable. Optionally, two-way free-space communication occurs between thestationary transceiver31 of theCCU28 andtransceiver24 of thebridge1. EveryCCU28 is responsible for apassenger boarding bridge1 and for a predetermined section of space adjacent the passenger boarding bridge. Whenever anaircraft21 enters this predetermined section of space, theCCU28 assumes control over taxiing functions of theaircraft21, so as to guide theaircraft21 to an expected stopping position in an automated manner.
In use, thetransceiver22 aboard theaircraft21 transmits a “call” signal as described supra. The “call” signal is received by thestationary transceiver31 of theCCU28. Preferably, the “call” signal is a class specific “call” signal, which includes data relating to the class of theaircraft21. TheCCU28 also senses positional and trajectory information relating to the approachingaircraft21. To this end, additional sensors (not shown) are disposed on or about theCCU28 for sensing the approach of theaircraft21. Based upon the received “call” signal and the sensed approach information relating to theaircraft21, theCCU28 determines instructions for guiding the approachingaircraft21 to an expected stopping position for the specific class of aircraft. Furthermore, theCCU28 usesstationary transceiver31 to emit a control signal for reception bytransceiver22 aboard theaircraft21. In the instant embodiment, thetransceiver22 is in communication with the central computer (not shown) of theaircraft21, such that theCCU28 may control theaircraft21 remotely. In this fashion, theCCU28 controls theaircraft21 during its approach to the expected stopping position adjacent thepassenger boarding bridge1.
TheCCU28 provides to thebridge controller7 of thepassenger boarding bridge1, via thetransceiver24, the data relating to the class of theaircraft21 as well as the sensed positional and trajectory information relating to the approachingaircraft21. For instance, the data relating to the class of theaircraft21 includes doorway height, front and rear doorway separation, expected stopping position of the type of aircraft, etc. Accordingly, the passenger boarding bridge may begin moving toward the expected stopping position of theaircraft21 in advance of theaircraft21 coming to a complete stop. Final adjustments for aligning thepassenger boarding bridge1 to the doorway of the aircraft are performed under the control of thebridge controller7 using signals provided from proximity sensors located near the cabin end of the bridge. The proximity sensors are used to determine the exact position of theaircraft doorway20, and to activate a bridge auto level system (not shown) after the bridge is aligned. Thebridge1 will also carry safety sensors (not shown), which will ensure that there is no unwanted contact between theaircraft21 and thebridge1. Preferably, the system is designed such that a closed communication circuit exists between theaircraft21, theCCU28 and thebridge1.
Furthermore, the pilot can deactivate the system described with reference toFIG. 4 by activating a master switch located aboard theaircraft21, preferably within the flight deck ofaircraft21. If the pilot has deactivated the system, then theaircraft21 emits a “not active” signal when it approaches the parking area. In turn, theCCU28 instructs the pilot to stop, and to wait for ground crew to prepare for a manned or a semi-automated docking sequence.
Referring toFIG. 15, shown is a system according to a sixth embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated inFIG. 14. According to the sixth embodiment afourth transceiver30 is provided at a stationary point along thepassenger boarding bridge1. Optionally, thefourth transceiver30 is positioned at a stationary point being other than along thepassenger boarding bridge1, such as for instance along a wall surface of theterminal building3. Advantageously, triangulation methods may be used to determine the position of either one of thenon-stationary transceivers22 and24, based upon the known positions of thefourth transceiver30 and thestationary transceiver31. In this way, thetransceiver24 can be guided to arrive at a same point occupied bytransceiver22, so as to engage the cabin end of thepassenger boarding bridge1 with thedoorway20 ofaircraft21.
It is an advantage of the third through sixth embodiments of the instant invention that an authorized user may reconfigure thetransceiver22, so as to change the class specific signal that is emitted, in order to accommodate a different class of aircraft. Accordingly, one type oftransceiver22 can be manufactured and subsequently configured by an authorized user to represent a desired class of aircraft. Furthermore, if an aircraft type is retired or otherwise changed, then thetransceiver22 can be salvaged and reconfigured for use with a different type of aircraft. Of course, the reconfiguration of thetransceiver22 requires correct authorization, in order to ensure safe operation of the system. Further advantageously, thetransceiver22 supports use with a large plurality of types of aircraft. For example, using a simple 8 bit-encoding scheme, it is possible to represent 256 different types of aircraft.
The first through sixth embodiments of the instant invention, as described above, involve aligning thereceiver unit23,33 ortransceiver unit24,94 carried by thepassenger boarding bridge1 with thetransmitter unit29,39 ortransceiver unit22,93 carried by theaircraft21. Some methods suitable for performing such an alignment operation are discussed in greater detail below, by way of specific and non-limiting examples.
Referring now toFIGS. 16aand16b, shown is a first method of aligning thereceiver unit23,33 ortransceiver unit24,94 carried by thepassenger boarding bridge1 with thetransmitter unit29,39 ortransceiver unit22,93 carried by theaircraft21. In this specific example, thewireless receiver73 of the illustratedreceiver unit23 includes a plurality ofsensors160 disposed about thepassenger boarding bridge1, eachsensor160 in operative communication with thereceiver unit23. Thetransmitter unit29 includes awireless transmitter70, whichwireless transmitter70 is configured for providing a plurality of optical signals, each optical signal directed to propagate along a different path. The aircraft engaging end of thebridge1 is moved, thereby moving the plurality ofsensors160 until eachsensor160 detects an optical signal of the plurality of optical signals. When thebridge1 is precisely aligned with the doorway of the aircraft in the horizontal and vertical directions, then the bridge controller extends the aircraft engaging end of thebridge1 directly toward theaircraft21 until the inductive proximity sensors (not shown) indicate close approach of thebridge1 to the aircraft, at which time the rate of approach is decreased automatically. A pressure sensor (not shown) stops the movement of the bridge upon contact with theaircraft21.
Referring now toFIGS. 17aand17b, shown is a second method of aligning thereceiver unit23,33 ortransceiver unit24,94 carried by thepassenger boarding bridge1 with thetransmitter unit29,39 ortransceiver unit22,93 carried by theaircraft21 involving the use of a direction indicating receiver. In the specific example shown inFIG. 17, thetransmitter unit29 and the receiveunit23 are illustrated. Thetransmitter unit29 emits an optical signal, for instance a directed beamoptical signal161. Optionally, the optical signal is not a directed beam, and thereceiver unit23 includes a lens (not shown) for focusing the optical signal onto a detector element, for instance a charge couple device (CCD)detector162 of thereceiver unit23. TheCCD detector162 comprises a plurality of rows (not shown) and a plurality of columns (not shown) of CCD elements. For simplicity, only oneCCD element163 is illustrated. Then, the element on the CCD at which the optical signal impinges is indicative of an alignment status. If the optical signal source of thetransmitter unit29 is at a same height as thedetector element163 of thereceiver unit23, that is when in alignment, then the bridge is raised until theCCD element163 in a predetermined row is “lit” by the optical signal. Next, the end of the bridge is moved laterally until theCCD element163 in a predetermined column is “lit”. Accordingly, asingle CCD element163 is “lit” at the correct row and column. Then the bridge is moved toward thetransmitter unit29 along a straight path. If more than one sensor becomes “lit”, then the alignment process outlined above is performed to realign the bridge to the doorway of the aircraft. When the end of the bridge is in close proximity to the aircraft, as indicated by proximity sensors, more than one CCD element may be “lit”, and the average locations of the more than one “lit” CCD element is used. Of course, the position of the end of thebridge1 is repeatedly adjusted as the bridge is extended toward the aircraft, such that any angular misalignment between the end of thebridge1 and theaircraft doorway21 is corrected.
Referring now toFIG. 18, shown is a third method of aligning thereceiver unit23,33 ortransceiver unit24,94 carried by thepassenger boarding bridge1 with thetransmitter unit29,39 ortransceiver unit22,93 carried by theaircraft21 involving a triangulation method. Triangulation is a process by which the location of a radio transmitter can be determined by measuring either the radial distance, or the direction, of the received signal from two or three different points. In the specific example shown inFIG. 18, thetransceiver22 and thetransceiver24 are illustrated as the moveable transceivers, andtransceiver26 is stationary. Preferably, thetransceivers24 and26 each include a directional antenna.
Referring now toFIGS. 19aand19b, shown is a fourth method of aligning thereceiver unit23,33 ortransceiver unit24,94 carried by thepassenger boarding bridge1 with thetransmitter unit29,39 ortransceiver unit22,93 carried by theaircraft21 involving a triangulation method. Triangulation is a process by which the location of a radio transmitter can be determined by measuring either the radial distance, or the direction, of the received signal from two or three different point. In the specific example shown inFIGS. 19aand19b, thetransceiver22 and thetransceiver24 are illustrated as the moveable transceivers, andtransceivers26 and30 are stationary. The exact position of eachtransceiver22,24 is determined as described with reference toFIG. 18, and the passenger boarding bridge is adjusted until thetransceiver24 carried at the aircraft engaging end thereof is substantially adjacent thetransceiver22 aboard theaircraft21.
Optionally, a Biris (bi-iris) system, i.e. imaging onto a position sensitive photodetector through an apertured mask, is used to measure location and distance. The Biris system uses a laser to form a target as well as a dual iris detector for forming an image with two separately imaged views of the target. This permits verification of target position and increased accuracy. An advantage of the Biris system is its small size and the robustness of the range sensor.
Of course, when the type of theaircraft21 is known, for example when thetransceiver22 aboard the aircraft transmits a class specific “call” signal, then the passenger boarding bridge can be preset to a position close to the expected stopping position of thedoorway20 of theaircraft21. The final adjustments can be made by using thetransceiver24 aboard the passenger boarding bridge to home in on thetransceiver22 based upon the signal strength of the signal being transmitted by thetransceiver24. Accordingly, it is possible to align the passenger boarding bridge to thedoorway20 of theaircraft21 using a system comprising at minimum a single transmitter aboard theaircraft21 and a single receiver aboard the passenger boarding bridge. Optionally, the passenger boarding bridge is preset to a correct height for the specific type of aircraft in dependence upon the class specific “call” signal, and only the horizontal position of the passenger boarding bridge is adjusted by “homing in” on the “call” signal.
It is a further advantage of the instant invention that the use of optical signals and/or RF signals for aligning thepassenger boarding bridge1 with thedoorway20 ofaircraft21 does not pose any danger to the vision of flight crew members, passengers or ground crew members. When optical signals are used, such as for instance infrared signals, interference with airport communication systems, flight navigation systems and/or the operations of nearby passenger boarding bridges is avoided. Still further advantageously, for the expected operating distances of the instant invention, the infrared signals are substantially unaffected by adverse environmental conditions such as snow, fog, rain, darkness, etc. Preferably, the infrared transceivers and/or receivers are in communication with temperature compensating circuits, so as to allow reliable operation over a wide range of temperature values.
Furthermore, the ancillary information transmitted from the aircraft based transmitter unit to the passenger boarding bridge can be used in an automated airport billing system, wherein an airline is billed according to the number of seats and/or the number of passengers aboard each flight that is serviced by the passenger boarding bridge. Of course, the ancillary information may also relate to, for instance, a sensed internal cabin temperature of the aircraft. In the latter case, the ancillary information is used to control a preconditioned air unit for maintaining the internal cabin temperature of the aircraft within a predetermined range of values. In this way, aircraft that are parked for long periods of time or even over night in a cold climate may be reliably heated at a constant temperature so as to prevent freezing, and in a secure manner that does not require one of the doorways to be left unsecured so as to introduce a wired temperature sensor into the interior cabin of the aircraft.
Referring now toFIG. 20, shown is a flow diagram of a method of confirming the authenticity of a “call” signal received by the transceiver unit aboard thepassenger boarding bridge1, according to yet another embodiment of the instant invention. The aircraft based transceiver unit provides a “call” signal, which is optionally one of a generic “call” signal and a class specific “call” signal. The “call” signal is provided either as the aircraft approaches the passenger boarding bridge, or after the aircraft has come to a stop adjacent the passenger boarding bridge. Upon detecting the “call” signal, the bridge based transceiver unit provides a confirmation code for reception by the aircraft based transceiver unit. If the aircraft based transceiver unit is actively calling for the passenger boarding bridge then, upon detecting the provided confirmation code, the aircraft based transceiver unit returns the confirmation code to the bridge based transceiver unit. The bridge based transceiver unit detects the returned confirmation code and, if the expected confirmation code has been returned, bridge alignment proceeds as normal. If the expected confirmation code is not detected, then the bridge re-transmits the confirmation code, or optionally returns an error message and calls for a human operator to manually complete the alignment operation.
The method according toFIG. 20 allows the bridge based transceiver unit to confirm that a detected “call” signal is authentic. For instance, a bridge based transceiver unit that is adapted to detect optical signals may mistake an ambient light source, such as for instance sunlight reflected off of a windshield or a flashing light of an emergency vehicle, for a call signal from an aircraft based transceiver. Of course, unexpected movement of the passenger boarding bridge in response to such ambient light signals could put airport personnel and/or equipment at risk. Advantageously, the method ofFIG. 20 requires confirmation from a genuine aircraft based transceiver unit before the bridge begins to move. Further advantageously, if more than one bridge based transceiver unit detects the “call” signal, then the aircraft based transceiver unit will receive a corresponding number of confirmation requests. When the aircraft based transceiver unit becomes “aware” that plural bridges have responded to the “call” signal, then a further exchange of signals is performed in order to resolve the conflict, and to ensure that only the desired passenger boarding bridge or bridges begin alignment operations.
Referring toFIG. 21, a seventh embodiment of the invention is shown. Elements labeled with the same numerals have the same function as those illustrated inFIG. 1.Aircraft21 includes atransceiver22 for transmitting one of an optical signal and an RF signal and for receiving one of an optical signal and an RF signal. Preferably, thetransceiver22 is disposed within a window (not shown) of thedoorway20 to which apassenger boarding bridge1 is to be connected. Thetransceiver22 is intended for use only during the aircraft docking and passenger boarding bridge alignment operations. Thetransceivers22 are in communication with acontrol module2100. Thecontrol module2100 conveniently allows a member of the flight crew of the aircraft to provide a signal to thetransceiver22. Thetransceiver22 then provides a control signal to thepassenger boarding bridge1.Passenger boarding bridge1 includes atransceiver24, for receiving the one of an optical signal and an RF signal transmitted from the aircraft mountedtransceiver22 and for transmitting the one of an optical signal and an RF signal to be received by thetransceiver22 ofaircraft21. Accordingly, two-way communication occurs between theaircraft21 and thepassenger boarding bridge1, which permits the implementation of active methods of alignment. In this embodiment, a member of the flight crew provides an input signal to thecontrol module2100 indicative of one of: a docking request, an undocking request and an emergency stop. A signal is provided from thecontrol module2100 to the aircraft mountedtransceiver22. Thetransceiver22 then transmits the instruction signal to thetransceiver24 mounted on thebridge1. Additionally, a homing signal is also provided from thetransceiver22. Thetransceiver24 mounted to thebridge1 is for providing signals indicative of a state of thebridge1. Example states of the bridge include: awaiting instruction, docking in progress, docking complete, undocking in progress, undocking complete, error: unable to dock.
Referring toFIG. 22, a flow chart is provided indicative of the steps associated with the use of the seventh embodiment of the invention. Specifically, the aircraft stops proximate the bridge, a member of the flight crew aboard the aircraft activates the aircraft transceiver. The transceiver provides a signal to the bridge indicative of the type of aircraft, the class of the aircraft and a request to initiate an automated docking sequence. The aircraft transceiver emits a homing signal that is useable by a transceiver on the bridge to determine the position and angle of the bridge relative to the aircraft. Clearly, using such a system it is not necessary for the aircraft to stop at an exact location. When the aircraft stops at a position that is somewhat displaced from the ideal docking position the homing signal from the aircraft is used to position the bridge relative to the position of the door of aircraft. Once the bridge has successfully docked, a docking complete signal is provided from the bridge transceiver to the aircraft transceiver thereby informing the aircraft flight crew that it is safe to open the door to the bridge. Later, when the aircraft is ready to depart, a member of the flight crew aboard the aircraft causes the aircraft transceiver to provide an undocking request. The bridge transceiver receives this signal, the bridge begins an undocking procedure and the bridge transceiver emits an “undocking in progress” signal. Since a bridge provided according to this embodiment of the invention does not typically use a human operator it is convenient for the bridge to provide a signal to the aircraft transceiver in the event that the diagnostic test of the bridge reveals a problem. For example, a bridge made according to this embodiment of the invention uses a wheel to support the weight of the bridge. A member of the flight crew provides a “docking request” instruction to the bridge. The bridge acknowledges the instruction and begins approaching the aircraft. Unfortunately, the member of the flight crew fails to notice an obstruction on the ground near the aircraft. When the bridge is extending to meet the aircraft the wheel interferes with the obstruction. Upon sensing the interference, the bridge provides an error signal to the transceiver of the aircraft. The member of the flight crew is then able to contact airport support staff to investigate and rectify the problem.
Referring toFIG. 23, an eighth embodiment of the invention is shown. Elements labeled with the same numerals have the same function as those illustrated inFIG. 1. Aircraft21aincludestransceivers22aand22b, each for transmitting one of an optical signal and an RF signal and each for receiving one of an optical signal and an RF signal. Preferably, each of thetransceivers22aand22bis disposed within a window (not shown) of acorresponding doorway20aand20b. Passenger boarding bridges1aand1bare provided for docking todoorways20aand20brespectively. Each of the passenger boarding bridges1aand1binclude atransceiver24aand24brespectively, for receiving the one of an optical signal and an RF signal transmitted from theaircraft21 and for transmitting the one of an optical signal and an RF signal to be received by thetransceivers22aand22bofaircraft21. Acontrol module2300 is provided in the cockpit thereby permitting a member of the flight crew, henceforth referred to as the pilot, to provide instructions to thetransceivers22aand22b. An input port on the control module permits different modes of operation. In a first mode of operation, each of thetransceivers22aand22bis operated independently, thus while afirst transceiver22ais controlled to provide a request docking instruction topassenger boarding bridge1a, anothertransceiver22bprovides a request docking instruction topassenger boarding bridge1b. In second mode of operation the pilot designates which transceivers of the set oftransceivers22aand22bare to be controlled and which are to remain inactive. When thetransceivers22aand22bare activated they provide a signal indicative of the aircraft class and the location of the doorway corresponding to the transmitting transceiver. This information is sufficient to determine a path for the passenger boarding bridge that will permit it to dock with the aircraft without inadvertently colliding with the aircraft, provided such a path exists. Thus, a properly configured passenger boarding bridge will automatically adjust to the correct height of the doorway and dock with the doorway automatically and safely. A person of skill in the art will perceive that this embodiment of the invention is useable with any suitable number of doorways and passenger boarding bridges. Clearly, when the number of doorways of an aircraft is large it is convenient to provide a display with the controller. The display assists the pilot in recognizing, for example, which of the doorways have an aircraft boarding bridge in a position to permit docking, the status of the aircraft boarding bridge, the status of thetransceivers22aand22b, error signals and other status indications. It is suggested that the data display be an array of light emitting diodes with a transparent overlay representative of the geometry of the aircraft disposed thereon however this need not be the case as numerous other configurations of the data display are easily envisioned by a person of skill in the art. Additionally, as thetransceivers22a,22b,24aand24bare all in communication with thecontrol module2300 it is a simple matter to provide a feed back signal to the passenger boarding bridge. Thus, the data display of thecontrol module2300 optionally indicates the perceived distance between the passenger boarding bridge and the aircraft doorway. In this way a displacement feedback loop has been formed using the status signal.
Optionally, passenger boarding bridges1aand1bare aligned todoorways20aand20b, respectively, using only a single transceiver, for instance one oftransceiver22aandtransceiver22baboard the aircraft21a. For instance,transceiver22atransmits one of an optical signal and an RF signal for guiding thepassenger boarding bridge1atoward thedoorway20aof aircraft21a. Since the position of thedoorway20brelative to thedoorway20ais known, for a known type of aircraft, thetransceiver22amay also be used to transmit one of a second optical signal and a second RF signal for guiding thepassenger boarding bridge1bto thedoorway20bof aircraft21a. For instance, thepassenger boarding bridge1a“homes in” directly on the signal transmitted fromtransceiver22a, until thetransceiver24adisposed aboard thepassenger boarding bridge1ais substantially aligned with thetransceiver22adisposed aboard the aircraft21a. Similarly, thetransceiver24bdisposed aboard thepassenger boarding bridge1b“homes in” on a “virtual homing signal” transmitted fromtransceiver22a. For instance, the “virtual homing signal” includes information for locating thedoorway20busing the signal transmitted fromtransceiver22a. Optionally, a controller disposed aboard thepassenger boarding bridge1bprovides a control signal, in dependence upon the type of aircraft, for guiding thepassenger boarding bridge1bto thedoorway20busing the signal transmitted fromtransceiver22a.
Referring now toFIG. 24, shown is a system according to a ninth embodiment of the instant invention. Elements labeled with the same numerals have the same function as those illustrated atFIG. 21.Aircraft21 includes atransceiver22 including a transmitter portion for transmitting one of an optical signal and an RF signal, and including a receiver portion for receiving one of an optical signal and an RF signal. Thetransceiver22 is preferably disposed along a length of theaircraft21 about a point proximate thedoorway20 to which apassenger boarding bridge1 is to be connected. Unlike the first through eighth embodiments of the instant invention, thetransceiver22 according to the ninth embodiment is preferably disposed within a not illustrated space or hollow space that is defined between an inner wall of an aircraft side-wall and an outer wall of the same aircraft side-wall. Thetransceiver22 is preferably in communication with acontrol module2100. Thecontrol module2100 comprises a user interface disposed, for example, within a cockpit portion of the aircraft for receiving an indication from a user for initiating an operation for aligning the one end of the passenger loading bridge to the doorway of the aircraft, and for providing a signal in dependence upon receiving the indication. For example, thecontrol module2100 is provided as part of an after-market retrofit of the aircraft, for instance, in the form of one of a push-button switch mechanism, a touch sensitive monitor, a keyed lock-switch, a biometric input device, a token reader, and an alphanumeric or iconic keypad. Optionally, thecontrol module2100 is provided as a software package for execution on an existing processor of an on-board computer system. Thecontrol module2100 conveniently allows a member of the flight crew of the aircraft to provide an input signal to thetransceiver22. In dependence upon receiving from the control module2100asignal relating to the input signal, thetransceiver22 provides a control signal via the transmitter portion, the control signal including the one of an optical signal and an RF signal.
Optionally, thecontrol module2100 is in communication with a not illustrated second transmitter disposed aboard the aircraft, the second transmitter being responsive to signal from thecontrol module2100 for transmitting a second electromagnetic signal comprising an activation signal for initiating the operation for aligning the one end of the passenger loading bridge to the doorway of the aircraft. Further optionally, thecontrol module2100 is also in communication with a not illustrated third transceiver that is disposed along a length of theaircraft21 about a point proximate another doorway to which another passenger boarding bridge is to be connected. For instance, the third transceiver is disposed about a point proximate a rear doorway that is aft of or over a wing of the aircraft, for use by an over-the-wing passenger boarding bridge during alignment with the rear doorway. Of course, the third transceiver is preferably disposed within a not illustrated space or hollow space that is defined between an inner wall of an aircraft side-wall and an outer wall of the same aircraft side-wall.
Referring still toFIG. 24,passenger boarding bridge1 includes atransceiver24 including a receiver portion for receiving the control signal from the aircraft mountedtransceiver22, and a transmitter portion for transmitting the one of an optical signal and an RF signal to be received by thetransceiver22 ofaircraft21. Accordingly, the system according to the ninth embodiment of the instant invention supports two-way communication between theaircraft21 and thepassenger boarding bridge1, which in turn supports the implementation of active methods of alignment. For instance, according to the ninth embodiment of the instant invention a member of the flight crew provides to thecontrol module2100 an input signal indicative of one of: a docking request, an undocking request and an emergency stop. A signal relating to the input signal is provided from thecontrol module2100 to the aircraft mountedtransceiver22. Thetransceiver22 then transmits an instruction signal to thetransceiver24 mounted on thebridge1. Additionally, a homing signal is also provided from thetransceiver22. Thetransceiver24 mounted to thebridge1 is for providing signals indicative of a state of thebridge1. Example states of the bridge include: awaiting instruction, docking in progress, docking complete, undocking in progress, undocking complete, error: unable to dock.
Referring now toFIG. 25, shown is a simplified diagram of atypical doorway20, including awindow2400 provided therethrough, as viewed from a point external to theaircraft21. Disposed along the exterior surface of the side-wall about a point proximate the doorway and at approximately a height of the door sill is a doorarea exterior light2402. The doorarea exterior light2402 includes a not illustrated lamp mounted within a housing, which is riveted or otherwise secured into an opening through the side-wall of the aircraft. The lamp is protected by a lens of approximately 3 inches diameter, which is secured over the opening so as to be approximately flush with the exterior surface of the side-wall. Any suitable material, such as Lexan™ plastic, may be used for the lens material. Typically, the housing is fabricated from a rigid material such as aluminum and forms a recess of approximately 2 inches depth for containing the lamp. Advantageously, the housing, as well as the methods of installation of the housing, are known in the art and are certified for use with commercial aircraft.
Referring now toFIG. 26a, shown is a simplified diagram of adoorway20, including awindow2400 provided therethrough, as viewed from a point external to theaircraft21. Elements labeled with the same numerals have the same function as those illustrated atFIG. 25. Disposed along the exterior surface of the side-wall about a point proximate the doorway and at approximately a height of the door sill is a doorarea exterior light2402. Furthermore, atransceiver22 is provided according to the ninth embodiment of the instant invention. Thetransceiver22 is mounted within a housing, which is fixedly secured into an opening through the side-wall of the aircraft. For example, the housing is riveted or otherwise secured into place within the opening. Thetransceiver22 is protected by a lens of approximately 3 inches diameter, which is secured over the opening so as to be approximately flush with the exterior surface of the side-wall. Any suitable material that is transmissive to electromagnetic radiation within a range of the electromagnetic spectrum that is utilized by thetransceiver22 may be used for the lens material. The housing is fabricated from a suitable material, such as for instance aluminum, and forms a recess of approximately 2 inches depth for containing thetransceiver22. Advantageously, the housing, as well as the methods of installation of the housing, are known in the art and are certified for use with commercial aircraft. As shown inFIG. 26a, thetransceiver22 is disposed a known vertical distance, Δv, and a known horizontal distance, Δh, relative to a reference point of thedoor20, such as for example the center point ofdoor20.
Referring now toFIG. 26b, shown is a side cross sectional view of atransceiver22 mounted according to the ninth embodiment of the instant invention. Thetransceiver22 is disposed within a space orhollow space2404 between aninner wall2406 of an aircraft side-wall2408 and anouter wall2410 of the same aircraft side-wall2408. As shown atFIG. 26b, the space orhollow space2404 is further defined by ahousing2412, which is fixedly mounted within an opening through theouter wall2410 for supporting thetransceiver22. Known means, such as for example riveting, are used to fixedly mount the housing within the opening through theouter wall2410. Thetransceiver22 is protected by a lens2413 of approximately 3 inches diameter, which is secured over the opening so as to be approximately flush with the exterior surface of theouter wall2410. Thetransceiver22 is disposed within the space or hollow space at a known depth, Δd, relative to the exterior surface of theouter wall2410. Preferably, thetransceiver22 includes an optical transmitter portion for providing an electromagnetic signal including light within a predetermined region of the electromagnetic spectrum. One of skill in the art will appreciate that the material used to fabricate lens2413 should be transmissive to the light within the predetermined region of the electromagnetic spectrum. Thehousing2402 is configured to secure thetransceiver22 within the space orhollow space2404, and to support an electrical connection between thetransceiver22 and a not illustrated on-board power system of theaircraft21. Optionally, thehousing2402 is further configured to support a connection between thetransceiver22 and a processor aboard theaircraft21. The space orhollow space2404 is accessible via the opening through theouter wall2410.
Also shown atFIG. 26bis the doorarea exterior light2402, comprising alamp2414 secured within ahousing2416, which is fixedly mounted within another opening through theouter wall2410. Alens2418 of approximately 3 inches diameter, which is secured over the other opening so as to be approximately flush with the exterior surface of theouter wall2410, protects thelamp2414.
Referring now toFIG. 27, shown is a side cross sectional view of atransceiver22 mounted according to a tenth embodiment of the instant invention. Thetransceiver22 is disposed within a space orhollow space2420 between aninner wall2406 of an aircraft side-wall2408 and anouter wall2410 of the same aircraft side-wall2408. Since no opening is provided through theouter wall2410, thetransceiver22 preferably transmits and receives signals within a radio-frequency portion of the electromagnetic spectrum. Also shown atFIG. 26bis the doorarea exterior light2402, comprising alamp2414 secured within ahousing2416, which is fixedly mounted within an opening through theouter wall2410. Alens2418 of approximately 3 inches diameter, which is secured over the opening so as to be approximately flush with the exterior surface of theouter wall2410, protects thelamp2414. Since the transceiver is not readily accessible within the space orhollow space2420, preferably the transceiver is mounted during manufacture of the aircraft.
Referring now toFIG. 28, shown is a side cross sectional view of atransceiver22 mounted according to an eleventh embodiment of the instant invention. Thetransceiver22 is disposed within a space orhollow space2422 between aninner wall2406 of an aircraft side-wall2408 and anouter wall2410 of the same aircraft side-wall2408. As shown atFIG. 28, the space orhollow space2422 is further defined by ahousing2424, which is fixedly mounted within an opening through theinner wall2406 for supporting thetransceiver22. Known means, such as for example riveting, are used to fixedly mount thehousing2424 within the opening through theinner wall2406. Thetransceiver22 is protected by a not illustrated cover, which is secured over the opening so as to be approximately flush with the interior surface of theinner wall2406. Thetransceiver22 is disposed within the space or hollow space at a known depth, Δd, relative to the exterior surface of theouter wall2410. Preferably, thetransceiver22 includes a radio frequency transmitter portion for providing an electromagnetic signal within the radio frequency region of the electromagnetic spectrum. Thehousing2424 is configured to secure thetransceiver22 within the space orhollow space2422, and to support an electrical connection between thetransceiver22 and a not illustrated on-board power system of theaircraft21. Optionally, thehousing2424 is further configured to support a connection between thetransceiver22 and a processor aboard theaircraft21. The space orhollow space2422 is accessible via the opening through theinner wall2406.
Also shown atFIG. 28 is the doorarea exterior light2402, comprising alamp2414 secured within ahousing2416, which is fixedly mounted within another opening through theouter wall2410. Alens2418 of approximately 3 inches diameter, which is secured over the other opening so as to be approximately flush with the exterior surface of theouter wall2410, protects thelamp2414.
Thetransmitters29 and39 of the first and second embodiments, respectively, thetransceiver22 of the third through seventh and ninth through eleventh embodiments, and thetransceivers22aand22bof the eighth embodiment are intended for use only during the aircraft docking and passenger boarding bridge alignment operations. To this end, thetransmitters29 and39 and thetransceivers22,22a, and22bare preferably a part of a not illustrated “weight-on-wheels” (WOW) system of the aircraft. The WOW system includes a not illustrated power bus for providing power to certain systems of the aircraft in dependence upon the weight of the aircraft being supported by not illustrated landing gear. Subsequent to the aircraft “taking off” from the runway and becoming airborne, the WOW system automatically disables those systems that are not intended for use during flight.
Embodiments of the invention described hereinbefore make use of a transmitter or a transceiver including a transmitter portion aboard an aircraft and a receiver aboard a passenger boarding bridge to assist in the alignment of the passenger boarding bridge relative to the aircraft. The data provided from the transmitter or transmitter portion need not be limited to simple docking instructions. For example, information regarding the aircraft model and version optionally is transmitted along with data indicative of the position of a passenger doorway of the aircraft relative to the location of the transmitter or transmitter portion. Additionally, the transmitter or transmitter portion optionally provides data indicative of the flight number, the airline and the number of passengers aboard the flight. This data is useful to the management of the airport as the airlines are often billed for their use of the terminal and the number of passengers that they service. Thus, the data is easily calculated at the time when the passengers are moving between the airport and the aircraft.
As is illustrated by the following, non-limiting example, the exchange of information between a transmitter disposed aboard the aircraft and a receiver disposed aboard the passenger boarding bridge need not be limited to signals for aligning the passenger boarding bridge to a doorway of the aircraft. For instance, a cabin temperature sensor may be provided in communication with the transmitter disposed aboard the aircraft for sensing a temperature of the cabin and for providing a signal relating to the sensed temperature to the transmitter. The signal relating to the sensed temperature may then be wirelessly transmitted to the receiver disposed aboard the passenger boarding bridge, for use by a pre-conditioned air unit in maintaining the cabin temperature within a predetermined range of values. Accordingly, in cold climates, the transmitter is used to send a minimum temperature signal to the pre-conditioned air unit via the receiver disposed aboard the passenger boarding bridge, as soon as the cabin temperature drops to a predetermined value. Since the signal relating to the sensed temperature is provided wirelessly, the aircraft doorways may be locked and secured, and the passenger boarding bridge moved away from the aircraft, whilst maintaining the cabin temperature within a predetermined ranged of values. Such a system restricts access into the aircraft and thereby increases security, especially when the aircraft is parked for long periods of time or even over-night. In contrast, prior art systems use a wired sensor, which typically must be introduced into the cabin via an open and unsecured doorway.
Optionally, any one of thetransmitters29 and39 of the first and second embodiments, respectively, thetransceiver22 of the third through seventh embodiments, and thetransceivers22aand22bof the eighth embodiment is optionally disposed within a space or hollow space of an aircraft side-wall, in a manner substantially similar to that described with reference to one of the eighth through eleventh embodiments.
Numerous other embodiments may be envisaged without departing from the spirit and scope of the invention.