JP6931009B2 - Lamp service control system and method - Google Patents

Description

The present invention relates to a lamp service control system and method. More specifically, the present invention relates to a ramp service control system and method for use at an airport to control a ramp service operation provided by a ground operator within the airport.

Technical ramp service is an aspect of aircraft ground handling that allows the aircraft to be serviced at the airport. Ramp services include, but are not limited to, aircraft pushback and towing, aircraft guidance, ground-to-cockpit communication, water and toilet services, ground power supply, air conditioning and air starters. Includes service provision, mobile step / air bridge service for passengers to board and disembark from aircraft.

Most of the ramp services include the movement of large vehicles and the operation of ground equipment on aircraft.

Traditionally, ramp service operations operate in a central control center that prints flight assignment paper documents for each ground operator. The ground operator needs to go to the central control center, collect a printout of the flight assignment, and then head to the correct location at the airport to complete the flight assignment.

Each ground operator carries a radio (walkie-talkie) to receive updates from the central control center. For example, the central control center may inform the radio of the details of the flight assignment change to the ground operator by radio for immediate action by the ground operator.

One problem with this traditional ground service system is that the ground operator working from the flight assignment printout is not in time for the flight assignment update. The operator continues with a printout of the flight assignment that has not been updated. This can cause ground operators to make mistakes, resulting in service mistakes and flight delays.

A further problem with this conventional system is that ground operators are required to perform ground service tasks while simultaneously listening and communicating via radios. This is dangerous. Especially when the ground operator is driving a large vehicle, there is a risk that the ground operator loses concentration and crashes the vehicle. This danger not only endangers the lives of ground operators, but also the lives of other ground operators and potentially the lives of aircraft passengers and personnel.

It is an object of the present invention to provide an improved lamp service control system and method.

According to one aspect of the present invention, a lamp service control system used at an airport, the central control station configured for wireless communication, and the central control station configured to be carried by each operator for wireless communication. Each mobile device includes a communication unit configured to wirelessly receive a lamp service command from a central control station and a lamp service command visually delivered to the operator, including multiple mobile devices configured to do so. A screen configured to output and an input device configured to receive input from the operator in response to received lamp service instructions, the communication unit provides data indicating input from the operator. It is configured to transmit to the central control station, which is transmitted from the mobile device in response to the lamp service instruction and the lamp service instruction transmitted to the mobile device to control the lamp service operation in the airport. Allows you to monitor your response.

Preferably, each of the mobile devices is a wearable mobile device.

Conveniently, each mobile device is a smartwatch.

Advantageously, the screen of each mobile device is a touch screen.

Preferably, each of the mobile devices comprises a terrestrial navigation system using satellites configured to locate the mobile device, and the communication unit sends data indicating the determined position of the mobile device to the central control station. Configured to send.

Conveniently, each mobile device is equipped with an accelerometer configured to measure the acceleration or deceleration of the mobile device, and the communication unit centrally controls data indicating the measured acceleration or deceleration of the mobile device. It is configured to send to.

Advantageously, each mobile device comprises a digital compass configured to measure the direction of movement of the mobile device, and the communication unit is configured to transmit data indicating the direction of movement of the mobile device to a central control station. NS.

Preferably, the system further comprises a plurality of audio output devices, each audio output device being configured to be carried by the operator and providing the operator with audio output corresponding to a lamp service instruction.

Conveniently, each audio output device is a bone conduction headset.

Conveniently, each bone conduction headset is integrated into protective headgear and worn by the operator.

Preferably, the ramp service instruction is at least one of a flight assignment to the operator and a flight update to the operator.

Preferably, the ramp service instruction comprises at least one of an instruction, another instruction or warning to the operator to perform the lamp service task.

Conveniently, the central control station is configured to select a subset of multiple mobile devices and send ramp service instructions only to the selected subset of mobile devices.

Advantageously, the central control station is located, available, capable of operating specific equipment or performing specific lamp services, proximity to specific aircraft requiring specific lamp services, or mobile within the airport. It is configured to select a subset of mobile devices in response to one or more of the proximity to specific lamp equipment required to perform the lamp service of the staff wearing the device.

Preferably, the central control station includes a display unit configured to display a map of the airport and the relative position of each of the mobile devices within the airport.

Conveniently, the central control station's display unit is configured to display a subset of mobile devices that differ from other mobile devices on a map of the airport.

Advantageously, the display unit is the location of each staff member, availability, ability to operate specific equipment or perform specific lamp service, proximity to specific aircraft requiring specific lamp service or lamp service. Is configured to display one or more of the proximity to a particular lamp facility required to perform.

Preferably, the display unit displays one or more of the location, status and details of the lamp service required for a particular flight and / or the associated lamp equipment required to perform the lamp service. Configured to display.

According to another aspect of the invention, a method for controlling lamp service in an airport is provided, the method wirelessly to at least one mobile device carried by each operator with a lamp service command from a central control station. A step of transmitting, a step of receiving a lamp service instruction via at least one communication module of the mobile device, and a step of receiving a lamp service instruction to an operator carrying at least one mobile device via a screen in at least one mobile device. And the step of receiving input from the operator via the input device in at least one mobile device in response to the received lamp service instruction, and the central control station lamps in the airport. Data indicating input from the operator is sent to the central control station so that the lamp service instruction sent to the mobile device and the response sent from the mobile device can be monitored in response to the lamp service instruction to control the service operation. It has a step of transmitting.

Preferably, each of the mobile devices is a wearable mobile device.

Conveniently, each mobile device is a smartwatch.

Advantageously, the screen of each mobile device is a touch screen.

Preferably, each of the mobile devices comprises a terrestrial navigation system using satellites configured to position the mobile device, the method transmitting data indicating the determined position of the mobile device to a central control station. Including doing.

Conveniently, each mobile device is equipped with an accelerometer configured to measure the acceleration or deceleration of the mobile device, and the method sends data indicating the measured acceleration or deceleration of the mobile device to the central control station. Includes steps to send.

Advantageously, each mobile device comprises a digital compass configured to measure the direction of movement of the mobile device, the method comprising transmitting data indicating the direction of movement of the mobile device to a central control station.

Preferably, the method further comprises providing the operator with audio output corresponding to the lamp service instruction via an audio output device carried by the operator.

Conveniently, the audio output device is a bone conduction headset.

Advantageously, the bone conduction headset is integrated with the protective headgear and worn by the operator.

Preferably, the ramp service instruction is at least one of a flight assignment to the operator and a flight update to the operator.

Preferably, the ramp service instruction comprises at least one of an instruction, another instruction or warning to the operator to perform the lamp service task.

Conveniently, this method further comprises selecting a subset of multiple mobile devices and sending ramp service instructions only to the selected subset of mobile devices.

Advantageously, this method uses location, availability, ability to operate specific equipment or perform specific lamp services, proximity to specific aircraft requiring specific lamp services, or mobile devices in the airport. It further includes selecting a subset of mobile devices in response to one or more of the proximity to the particular lamp equipment required to perform the lamp service of the staff wearing the.

Preferably, the method further comprises displaying a map of the airport and the relative position of each of the mobile devices within the airport on the display unit of the central control station.

Conveniently, this method involves displaying a subset of mobile devices that differ from other mobile devices on a map of the airport.

Advantageously, this method is the location of each staff member, availability, ability to operate specific equipment or perform specific lamp service, proximity to specific aircraft requiring specific lamp service or lamp service. Includes displaying one or more of the proximity to a particular lamp facility required to perform.

Preferably, this method provides one or more of the location, status and details of the ramp service required for a particular flight and / or the associated ramp facility required to perform the ramp service. Including displaying.

An embodiment of the present invention will be described as an example with reference to the accompanying drawings so that the present invention can be understood more easily.

The schematic diagram of one lamp service control system which shows the embodiment of this invention. Schematic perspective view of a mobile device in the form of a smartwatch. A schematic perspective view of the smartwatch of FIG. 2 showing a first user interface. Schematic perspective view of the smartwatch of FIG. 2 showing a second user interface. Schematic perspective view of the smartwatch of FIG. 2 showing a third user interface. Schematic perspective view of an audio output device in the form of a bone conduction headset. Schematic perspective view of a protective headgear article with an integrated bone conduction headset. The schematic which shows the screen of the central control station of one Embodiment of this invention. The schematic view of the display output of the control screen of the central control station of FIG.

First, referring to FIG. 1 of the accompanying drawing, the lamp service control system 1 of the embodiment of the present invention includes a central control station 2. The central control station 2 is, in this embodiment, a computer terminal or server provided with a display screen or display unit (not shown). The central control station 2 includes a communication unit 3 configured to transmit and receive signals wirelessly. In embodiments of the present invention, wireless communication is performed using at least one or more of a wireless local area network (wireless LAN), WiFi® or cellular communication network.

The lamp service control system 1 further includes a plurality of mobile devices 4. In this embodiment, the mobile devices 4 are the same as each other. Each mobile device 4 is configured to be carried by each operator working on the ground in the airport. Each mobile device 4 includes a communication unit 5 configured to wirelessly receive a lamp service command and other commands or messages from the central control station 2. In embodiments of the present invention, the ramp service instruction comprises at least one of an instruction, another instruction or warning to the operator to perform the lamp service task. The ramp service instruction may or may not require an acknowledgment by the operator.

Each mobile device 4 comprises a screen (not shown in FIG. 1) configured to visually output or display a lamp service instruction or other received message to the operator.

Each mobile device 4 further comprises an input device (not shown in FIG. 1) configured to receive input from the operator in response to a received message or lamp service command. The communication unit 5 of each mobile device is configured to transmit data indicating an input from the operator to the central control station 2. Therefore, the central control station 2 may control the lamp service operation in the airport by monitoring the lamp service command transmitted to the mobile device 4 and the response transmitted from the mobile device 4 in response to the lamp service command. can.

Here, referring to FIG. 2 of the accompanying drawing, in a preferred embodiment, each mobile device 4 is preferably a smartwatch 6 configured to be worn on the operator's wrist 7. The smartwatch 6 includes, in this embodiment, a screen 8 which is a touch screen configured to receive touch input from the operator. In other embodiments, the smartwatch 6 does not include a touch screen, and in these embodiments, the input device is in the form of a button 9 provided on the body of the smartwatch 6. In a further embodiment, the smartwatch 6 is configured to receive input via the touch screen 8 and / or button 9.

In this embodiment, the mobile device 4 in the form of a smartwatch 6 preferably comprises a ground navigation system using satellites (not shown). The terrestrial navigation system using satellites is preferably a GPS receiver, but in other embodiments it may be a different terrestrial navigation system using satellites such as GLONASS.

The terrestrial navigation system using satellites is configured to detect the global position of the smartwatch 6 and transmit the position to the central control station 2 via the communication unit 5. With this implementation, the central control station 2 can monitor the respective positions of the smartwatch 6, and thus the position of the operator wearing the smartwatch 6.

The smartwatch 6 preferably further comprises an accelerometer (not shown) configured to measure the acceleration or deceleration of the smartwatch 6. For example, an accelerometer is configured to measure the acceleration or deceleration of a smartwatch 6 because the operator driving the vehicle carries the smartwatch 6. Therefore, the accelerometer can measure the acceleration or deceleration of the vehicle under the control of the operator. The smart watch 6 is configured to transmit acceleration / deceleration data to the central control station 2 via the communication unit 5. This data is used by the central control station 2 to detect anomalous acceleration or deceleration that may indicate dangerous vehicle movements and / or collision situations.

The smartwatch 6 preferably further comprises a digital compass (not shown) configured to measure the moving direction of the smartwatch 6 and transmit directional data to the central control station 2 via the communication unit 5. The central control station 2 uses the directional data to monitor the directional movements of the smartwatch 6 and its respective operators, eg, to monitor the direction of pushback or towing of the aircraft as it is moved by the operator. Monitor.

During use, the central control station 2 wirelessly transmits flight assignments to the mobile device 4. The mobile device 4 is hereinafter referred to as a smart watch 6 in this embodiment of the present invention.

Here, referring to FIG. 3 of the attached drawing, the lamp service instruction in the form of the flight assignment 10 is displayed on the screen 8 of the smart watch 6. The flight assignment 10 is displayed in detail on the screen 8 so that the operator can see the details of the flight assignment. The confirmation icon 11a is also displayed on the screen 8 so that the operator can give a touch input to the confirmation icon 11a to confirm that the operator completes the flight assignment. This confirmation input is transmitted to the central control station 2 by the smart watch 6.

The smartwatch 6 also preferably displays a rejection icon 11b on the screen 8. If the operator is unable or will not complete the flight assignment, the operator can provide an immediate rejection response by touching the rejection icon 11b. The smartwatch 6 sends a rejection response to the central control station 2 so that the central control station 2 can reassign flight assignments to another operator.

With reference to FIG. 4 of the accompanying drawings, the smartwatch 6 is preferably further configured to display a detailed flight assignment schedule 12 showing the plurality of flight assignments on the screen 8.

Providing flight assignments to the smartwatch 6 provides the operator with immediate notification, thereby avoiding the need for paper documents for flight assignments. The operator can receive flight assignments via the smartwatch 6 anywhere in the airport, eliminating the need for the operator to travel to the central control station. This avoids the time wasted by the operator moving to the central control station.

The flight assignment delivered directly to the smartwatch 6 is the latest flight assignment delivered to the operator in real time. This real-time delivery maximizes system efficiency and minimizes service processing errors.

System 1 is also configured to send updates to flight assignments to the smartwatch 6 in the manner described above for flight assignments. Flight updates provide real-time modifications or changes to flight assignments that operators can make immediately. These real-time updates minimize the potential for ramp processing errors when operators are working from outdated paper flight assignments.

Here, referring to FIG. 5 of the accompanying drawing, the smartwatch 6 is preferably configured to display additional control icons 13-15 on the screen 8. The operator can provide additional control inputs to the smartwatch 6 via these additional control icons 13-15 to provide additional feedback to the smartwatch 6 transmitted to the central control station 2. This additional feedback provides additional flexibility to the system for facilitating communication between the operator and the central control station 2.

With reference to FIG. 6 of the accompanying drawings, in a preferred embodiment of the invention, the system comprises each of a plurality of audio output devices carried by each operator. In this embodiment, each audio output device is a bone conduction headset such as the bone conduction headset 16 shown in FIG.

The bone conduction headset 16 includes a band 17 that fits around a portion of the operator's head. Bone conduction transducers 18 and 19 are located on both sides of the operator's head and are configured to transmit voice to the operator via vibrations transmitted through the operator's skull. The bone conduction headset 16 does not cover or close the operator's ear canal and does not prevent the operator from hearing the sounds of the surrounding environment. Therefore, the bone conduction headset 16 can be used to transmit audio to an operator wearing earplugs or mufflers to protect against loud noise.

The bone conduction headset 16 can also be used in place of conventional earphones to overcome the problem of conventional earphones blocking environmental sounds. The bone conduction headset 16 can be used more safely than conventional earphones, which may interfere with warnings to the operator in dangerous situations such as approaching vehicles.

The bone conduction headset 16 is preferably configured to wirelessly communicate with the smartwatch 6 so that the lamp service instruction can communicate from the smartwatch 6 to the bone conduction headset 16. The bone conduction headset 16 sends a lamp service instruction to the operator in audio format without the operator having to look at the screen 8 of the smartwatch 6. In another embodiment, the bone conduction headset 16 is connected to a radio transceiver that communicates directly with the central control station 2, and the bone conduction headset 16 receives the lamp service command directly from the central control station 2 via radio. Can be done.

With reference to FIG. 7 of the accompanying drawings, in a further embodiment, the bone conduction headset 20 is incorporated into a protective headgear article such as a bump cap 21. Operators wearing protective headgear can benefit from the improved safety aspects of the bone conduction headset 20 while still wearing protective headgear, for example when working under the wings of an aircraft.

The bone conduction headset of the embodiment of the present invention allows the operator to receive hands-free voice commands from the central control station 2. This eliminates the need for the operator to listen to the radio or press a button, which could lead to an accident, especially when the operator is driving the vehicle.

The audio device in the form of the bone conduction headset 16 in this embodiment preferably further comprises a microphone. The microphone allows bidirectional communication between the operator and the central control station 2 and with other mobile devices.

Here, referring to FIG. 8 of the accompanying drawing, the central control station 2 includes a display unit 22 for displaying information to the central manager 23 who supervises the lamp operation.

The display unit 22 is preferably a large display unit configured to display the airport map 24 together with other information.

With reference to FIG. 9 of the accompanying drawings, the display unit 22 preferably displays a map 24 with different colored or shaded sections to indicate different areas of the airport. The central control station 2 is configured to plot the location of each mobile device 4 around the airport on map 24 so that the central administrator 23 can see the current location of each mobile device 4, and thus each operator. NS.

The central manager 23 can easily identify which operator is in the right place to handle a particular ramp service operation, such as an operator in close proximity to an incoming aircraft. The central administrator 23 can then identify the subset 25 of the mobile device 4, as shown by the dotted line in FIG. The central control station 2 may choose to send the ramp service instruction only to a subset 25 of mobile devices. This avoids using bandwidth in the system by unnecessarily sending ramp service instructions to operators who are not in the right place to perform the required ramp service tasks.

In some embodiments, the central control station 2 is located, available, capable of operating specific equipment or performing specific lamp services, proximity to specific aircraft requiring specific lamp services, or Configured to select a subset of mobile devices in response to one or more of the proximity to specific lamp equipment required to perform the lamp service of staff wearing mobile devices in the airport Will be done.

In an embodiment of the invention, the central control station 2 allows the central administrator 23 to select staff to tailor equipment and / or flight to perform the required lamp service. Is configured to display additional information. Additional information is required to ensure the availability of each staff member, the ability to operate specific equipment or perform specific lamp services, the proximity to specific aircraft that require lamp service, or to perform lamp services. It is preferable to include one or more of the proximity to a specific lamp facility.

Additional information output via the display unit 22 is the location, status, and / or details of the lamp service required for a particular flight and / or the associated lamp equipment required to perform the lamp service. It is preferable to include one or more of the indications of.

As used herein and in the claims, the terms "include / include" and "include / include" and variations thereof include and include specified features, steps or integers. Means that. These terms should not be construed to rule out the presence of other features, steps or compounds.

The means for performing the disclosed functions or the methods or processes for achieving the disclosed results are disclosed in the above description expressed in a particular form, the claims below, or the accompanying drawings. Features are utilized to realize the present invention in its various forms, as needed, separately or in any combination of such features.

Claims (34)

A lamp service control system used at airports
With a central control station configured for wireless communication,
Each mobile device includes a plurality of mobile devices configured to be carried by each operator and wirelessly communicated with the central control station.
A communication unit configured to wirelessly receive a lamp service command from the central control station, and
A screen configured to visually output the lamp service instruction to the operator.
The communication unit includes an input device configured to receive an input from the operator in response to the received lamp service command, and the communication unit transmits data indicating the input from the operator to the central control station. The central control station is configured to provide a ramp service command sent to the mobile device and a response sent from the mobile device in response to the ramp service command to control the ramp service operation in the airport. to be able to monitor,
The ramp service instruction includes a flight assignment to the operator, the screen of each mobile device is a touch screen displaying a reject icon, and each mobile device has a reject icon if the operator is unable or will not complete the flight assignment. Sends the rejection response provided by touching to the central control station .
Lamp service control system. The lamp service control system according to claim 1, wherein each of the mobile devices is a wearable mobile device. The lamp service control system according to claim 1 or 2, wherein each mobile device is a smart watch. Each of the mobile devices comprises a terrestrial navigation system using satellites configured to determine the position of the mobile device, the communication unit centrally controlling data indicating the determined position of the mobile device. The lamp service control system according to any one of claims 1 to 3 , which is configured to transmit to a station. Each mobile device comprises an accelerometer configured to measure the acceleration or deceleration of the mobile device, and the communication unit provides data indicating the measured acceleration or deceleration of the mobile device to the central control station. The lamp service control system according to any one of claims 1 to 4 , which is configured to transmit to. Each mobile device comprises a digital compass configured to measure the moving direction of the mobile device, and the communication unit is configured to transmit data indicating the moving direction of the mobile device to the central control station. The lamp service control system according to any one of claims 1 to 5. The system further comprises a plurality of audio output devices, each of which is configured to be carried by an operator and is configured to provide the operator with audio output corresponding to the lamp service instruction. Item 6. The lamp service control system according to any one of Items 1 to 6. The lamp service control system according to claim 7 , wherein each audio output device is a bone conduction headset. The lamp service control system according to claim 8 , wherein each bone conduction headset is integrated with protective headgear and worn by an operator. The lamp service control system according to any one of claims 1 to 9 , wherein the lamp service instruction includes a flight update to the operator. The lamp service control system according to any one of claims 1 to 10 , wherein the lamp service instruction includes at least one of an instruction to an operator for performing a lamp service task, another instruction, or a warning. 13. The lamp service control system described. The central control station wears location, availability, the ability to operate specific equipment or perform specific lamp services, proximity to specific aircraft requiring specific lamp services, or mobile devices within the airport. 12. Claim 12 is configured to select a subset of mobile devices in response to one or more of the proximity to a particular lamp facility required to perform the lamp service of a staff member. Described lamp service control system. The lamp service control system according to any one of claims 1 to 13 , wherein the central control station includes a display unit configured to display a map of the airport and the relative position of each of the mobile devices in the airport. .. Display unit of the central control station is configured to display different subsets of the mobile device and other mobile devices on the map of the airport, the lamp service control system according to claim 14 dependent on claim 13. The display unit is for each staff location, availability, ability to operate specific equipment or perform specific lamp services, proximity to specific aircraft that require specific lamp services, or to perform lamp services. The lamp service control system according to claim 14 or 15 , which is configured to display one or more of the proximity to a particular lamp facility required for. The display unit displays one or more of the location, status and details of the lamp service required for a particular flight and / or the associated lamp equipment required to perform the lamp service. The lamp service control system according to any one of claims 14 to 16 , wherein the lamp service control system is configured as described above. A step of wirelessly transmitting a lamp service command from the central control station to at least one mobile device carried by each operator.
The step of receiving the lamp service instruction via at least one communication module of the mobile device, and
A step of visually outputting the lamp service instruction to an operator carrying the at least one mobile device via a screen in the at least one mobile device.
A step of receiving an input from the operator via an input device in the at least one mobile device in response to the received lamp service instruction.
A lamp service that comprises a step of transmitting data indicating input from the operator to the central control station, the central control station transmitting to the mobile device to control a lamp service operation in the airport. Allows monitoring of responses sent from mobile devices in response to instructions and said ramp service instructions .
The lamp service instruction has a flight assignment to the operator, the screen of each mobile device is a touch screen displaying a reject icon, and each mobile device has a reject icon if the operator is unable or will not complete the flight assignment. Sends the rejection response provided by touching to the central control station ,
A way to control the ramp service in the airport. The method of claim 18 , wherein each of the mobile devices is a wearable mobile device. The method of claim 18 or 19 , wherein each mobile device is a smartwatch. Each of the mobile devices comprises a terrestrial navigation system using satellites configured to position the mobile device, the method transmitting data indicating the determined position to the central control station. The method according to any one of claims 18 to 20, including the above. Each mobile device comprises an accelerometer configured to measure the acceleration or deceleration of the mobile device, the method providing data indicating the measured acceleration or deceleration of the mobile device to the central control station. the method according to any one of including transmitting, claims 18 to 21. A claim comprising each mobile device comprising a digital compass configured to measure the direction of movement of the mobile device, the method comprising transmitting data indicating the direction of movement of the mobile device to the central control station. The method according to any one of 18 to 22. The method according to any one of claims 18 to 23 , further comprising providing the operator with audio output corresponding to the lamp service instruction via an audio output device carried by the operator. 24. The method of claim 24, wherein the audio output device is a bone conduction headset. 25. The method of claim 25 , wherein the bone conduction headset is integrated with protective headgear and worn by an operator. The lamp service instructions include flight updates to operator A method according to any one of claims 18-26. The lamp service instructions, instructions for the operator to perform the lamp service task, including at least one of another instruction or warning method according to any one of claims 18-27. The method selects a subset of the plurality of mobile devices, the method according to any one of the only further comprising transmitting lamp service instruction, claims 18-28 subset of the mobile device selected. The methods include location, availability, the ability to operate specific equipment or perform specific lamp services, proximity to specific aircraft requiring specific lamp services, or wearing mobile devices within the airport. 29. The method of claim 29, further comprising selecting a subset of mobile devices in response to one or more of the proximity to a particular lamp facility required to perform the lamp service of a staff member. .. The method according to any one of claims 18 to 30 , further comprising displaying a map of the airport and the relative position of each of the mobile devices in the airport on the display unit of the central control station. The method on the map of the airport and other mobile devices includes displaying different subsets of the mobile device, The method of claim 31 dependent on claim 30. The method is for the location of each staff member, availability, ability to operate specific equipment or perform specific lamp services, proximity to specific aircraft requiring specific lamp services, or to perform lamp services. 31. The method of claim 31 or 32 , comprising displaying one or more of the proximity to a particular lamp facility required for. The method is to display one or more of the location, status and details of the lamp service required for a particular flight and / or the relevant lamp equipment required to perform the lamp service. 31. The method according to any one of claims 31 to 33.

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