Communications: electrical – Aircraft alarm or indicating systems
Reexamination Certificate
2001-11-26
2004-06-08
Tweel, John (Department: 2636)
Communications: electrical
Aircraft alarm or indicating systems
C455S430000, C370S347000
Reexamination Certificate
active
06747577
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to communications onboard an air vehicle and between an air vehicle and a ground control center such that the communications are controlled to ensure, among other things, that high priority communications that support the flight operations continually have sufficient communication bandwidth for transmission and reception by the air vehicle.
BACKGROUND OF THE INVENTION
While an air vehicle is in operation, various types of communications occur onboard the air vehicle and between the air vehicle and other locations. The communications include the transmission and reception of voice and data communications. For example, the flight crew may communicate with flight control personnel on the ground, the flight crew may communicate with the passengers via a public-address (PA) system, and the passengers may communicate via telephones or other electronics. Additionally, data such as updated weather information, entertainment programs and the like are oftentimes received by the air vehicle.
An air vehicle typically has a finite communication bandwidth that may be utilized to support all of the communications that occur onboard the air vehicle and between the air vehicle and other locations. The conventional process of supporting all of the air vehicle communications within the communication bandwidth involves allowing any type of voice or data communications to use a portion of the bandwidth if it is available, much like a first come, first serve basis. Until recently, the communication bandwidth for an air vehicle has been sufficient to support most, if not all, of the air vehicle communications without having different types of communications contending for the same portion of the bandwidth.
The quantity of voice and data communications that is desired to be transmitted between the air vehicle and the ground control center is increasing rapidly. For example, the computers onboard an air vehicle generate substantial amounts of data, at least some of which is desirably transmitted to the ground control center for review and analysis. Conversely, a ground control center oftentimes has access to large amounts of data that might be useful to the flight crew. In addition, passengers are carrying on more portable electronic devices, many of which also compete for a portion of the communications bandwidth. As such, the communications bandwidth may be quickly depleted, thereby preventing or at least delaying at least some communication.
Another example of increased communications between the air vehicle and the ground control center is illustrated in that, in the past, the ground control center only had the ability to transmit basic flight advisories to flight crew in the air vehicle, which merely provided an alert or warning to the flight crew. In addition, air vehicles only have had the ability to transmit basic flight data to ground control centers, leaving the detailed flight data to be recorded along with cockpit voices and instrumentation readings in the air vehicle's flight data recorder, and cockpit voice recorder, also known as the “black boxes.”
As described above, the quantity of air vehicle communications has increased and is anticipated to increase even more rapidly in the future. It is therefore possible that future air vehicle communications may exceed the existing communication bandwidth of the air vehicle. For instance, if a number of passengers are using onboard telephones or other electronic devices during the flight of the air vehicle, the passenger communications may occupy a significant amount of the available bandwidth. Thus, if the flight crew needs to transmit flight information to or receive flight information from the ground control center, there may not be enough communication bandwidth available to support the transfer of the flight information. Thus, the flight crew may not obtain or at least experience a delay in obtaining valuable flight information.
Therefore, a need in the industry exists to support increased communications onboard an air vehicle and between an air vehicle and other locations. In supporting the increased demand for the communications bandwidth, there is a need to insure that the most important communications that occur onboard the air vehicle and between the air vehicle and other locations continually have sufficient communication bandwidth such that they are not blocked or delayed by the monopolization of the communications bandwidth by other, less important types of communications. In particular, there is a need to ensure that the flight crew has the most complete and accurate information possible in order to permit them to make well-informed decisions that result in a safe and more efficient flight.
SUMMARY OF THE INVENTION
In this regard, the method and system of one embodiment monitor the communications onboard the air vehicle and between the air vehicle and the ground control center to insure that those types of communications that are considered the most important will always be supported and will not be blocked or delayed as a result of a monopolization of the communications bandwidth by other types of communication of lesser importance. Other aspects of the method and system of the present invention further assist in the safe flight of the air vehicle by permitting the air vehicle to be flown and landed while in an auto-pilot mode without further manual input, by displaying target settings of respective parameters provided by the ground control center, by providing detailed flight data to the air vehicle from the ground control center and by examining audio and/or video data in the ground control center that was captured onboard the air vehicle to identify individuals that may pose a security risk while the air vehicle is in flight.
In one advantageous embodiment of the present invention, a method and system are provided for selectively allocating the communication bandwidth supported by an air vehicle. In this regard, the air vehicle includes a communication system for transmitting and receiving different types of communication signals. In addition, a priority hierarchy is provided for the different types of communication signals based on the relative importance of the signals. The priority hierarchy may involve assigning a higher priority to communications between a ground control center and the air vehicle and assigning a lower priority to passenger communications. Additionally, the priority hierarchy of this embodiment may be stored in the data management controller of the air vehicle.
The air vehicle of this embodiment also includes a processing element. According to the system and method of this embodiment, the processing element is responsive to the priority hierarchy and monitors the communication signals transmitted to and from the air vehicle via the communication system. The processing element then dedicates portions of the communication bandwidth to predefined types of the communication signals based on the priority hierarchy. When dedicating the portions of the communication bandwidth, the portion of the communication bandwidth available to lower priority communication signals may be limited if higher priority communication signals are to be transmitted. In addition, the portion of the communication bandwidth dedicated to predefined types of communication signals may be reallocated as different types of signals are to be transmitted. To determine whether to dedicate a portion of communications bandwidth to a certain communication signal, the processing element may read a header associated with the communication signal to determine the type of the signal, and may then determine the relative importance of this type of communication signal based upon the priority hierarchy. To permit ongoing communications between the air vehicle and the ground control center, even if the communication bandwidth is otherwise occupied, a portion of the communication bandwidth may be permanently dedicated to communications between the air vehicle and the ground control center, thereby serving
Chakravarty Abhijit J. M.
Hamley James P.
Romanosky Joseph M.
Alston & Bird LLP
The Boeing Company
Tweel John
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