The present invention relates to a method and a device for automatically preventing unnecessary alerts produced by the anticollision systems carried onboard airplanes, upon a change of altitude, as well as an airplane provided with such a device.
It is known that most airliners are equipped with anticollision systems (generally called TCAS systems for Traffic Collision Avoidance Systems) which make it possible to ensure the safety of air traffic by preventing the risks of in-flight collision.
Thus, when two airplanes are converging towards one another, their anticollision systems calculate an estimate of the collision time and emit an alert informing the crews of each airplane of a possible future collision: such an alert is generally called a “traffic advisory” or “TA alert”. If appropriate, said anticollision systems emit moreover, for the attention of the crew, an order regarding an avoidance maneuver in the vertical plane so as to get out of the situation in which a collision is possible: such an avoidance maneuver order is generally called a “resolution advisory” or “RA alert”. The TA and RA alerts are manifested through voice messages and through the displaying of information in flight cabins.
In practice, an onboard anticollision system calculates a collision time in the horizontal plane (ratio of the horizontal distance of the two airplanes to their relative horizontal speed) and a collision time in the vertical plane (ratio of the vertical distance of the two airplanes to their relative vertical speed). Said collision times thus calculated are compared with predetermined thresholds for the TA alerts and for the RA alerts (said predetermined thresholds being moreover dependent on the altitude) and said alerts are triggered when said calculated collision times are less than the corresponding predetermined thresholds.
Moreover, it is known that frequently an airplane has to capture (while climbing or descending) a stabilized altitude level neighboring another altitude level allocated to another airplane and that, according to the rules of aerial navigation, two neighboring stabilized altitude levels are separated by only 300 m (1000 feet).
Hence, because of this small difference in altitude between stabilized altitude levels, the high vertical speed of modern airplanes and the weight of air traffic, said anticollision systems produce numerous TA and RA alerts, even though the airplane, shifting vertically so as to change altitude, is maneuvering correctly without any risk of collision with another airplane. These alerts induce a great deal of stress and are deemed operationally unnecessary by pilots, since the change-of-altitude maneuver is correct and their consideration leads to traffic disruption in most cases.
Moreover, the RA alerts during the altitude capture phases are very numerous and it is estimated that they currently represent more than 50% of the total of these alerts in European space, this percentage being apt to increase in the future owing to the expansion of air traffic.
The object of the present invention is to remedy this drawback.
To this end, by virtue of the invention, the method for limiting the number of alerts emitted by an anticollision system on board an airplane which performs a change-of-altitude maneuver comprising an approach phase followed by a phase of capture of a setpoint altitude associated with a predetermined setpoint execution deadline, said anticollision system being able to detect an intruder aircraft situated in the aerial environment of said airplane, to calculate a theoretical time for collision between said airplane and said intruder aircraft and to emit at least one alert when this theoretical collision time is less than a predetermined threshold, is noteworthy in that the following steps are carried out:
In a customary manner, the setpoint execution deadline for the capture phase can be determined by the automatic pilot of the airplane.
Thus, by virtue of the invention, by lengthening in a limited manner the duration of the capture phase (which may not exceed the maximum execution deadline), the untimely triggering of at least some of the RA and/or TA alerts is prevented. Furthermore, the change-of-altitude maneuver is precluded from being too long, which might disturb the pilots of the airplane and also the air traffic surrounding the latter, for example by compelling other aircraft in proximity to it to perform a trajectory modification.
Furthermore, it is possible to calculate an engagement altitude level for said capture phase. Thus, said airplane can be considered to be close to said setpoint altitude when the current altitude level of said airplane is between said engagement altitude level and said setpoint altitude.
Preferably, said engagement altitude level is determined with the aid of the following formula:
Ze=a−(Si+T)*Vzo
in which:
Furthermore, in the course of said capture phase, said control of the vertical speed of said airplane can be performed by controlling the load factor of said airplane defined with the aid of the following formula:
nz=k*(Vz−f(Z))
in which:
In the case where said setpoint altitude has not been reached after the expiry of said maximum execution deadline, said control of the vertical speed of said airplane can be performed by controlling the load factor of said airplane which is then defined by the following formula:
nz=k1*Z+k2*Vz
in which:
Moreover, said modified vertical speed profile comprises a first part associated with a trajectory of said airplane of exponential type, followed by a second part associated with a trajectory of said airplane of parabolic type.
Said first part of said profile can advantageously be described with the aid of the following function:
f1(Z)=(a−Z)/(Si+T)
in which:
Furthermore, said second part of said profile can be defined with the aid of the following function:
f2(Z)=√(α*0.1g*Z)
in which:
Moreover, the invention also relates to a device for the implementation of the method such as specified above making it possible to limit the number of alerts emitted by an anticollision system on board an airplane which performs a change-of-altitude maneuver comprising an approach phase followed by a phase of capture of a setpoint altitude associated with a predetermined setpoint execution deadline, said anticollision system being able to detect an intruder aircraft situated in the aerial environment of said airplane, to calculate a theoretical time for collision between said airplane and said intruder aircraft and to emit at least one alert when this theoretical collision time is less than a predetermined threshold.
According to the invention, such a device comprises:
Furthermore, the device can comprise means for calculating an engagement altitude level for said altitude capture phase.
The invention also relates to an airplane provided with the device such as mentioned above.
The figures of the appended drawing will elucidate the manner in which the invention may be embodied. In these figures, identical references denote similar elements.
The device 1 in accordance with the invention and schematically represented in
In
In a customary manner, the airplane AC is furthermore provided with an automatic pilot (not represented) able to control the change-of-altitude maneuver, which comprises in particular a capture phase (detailed in relation to
As shown by
The flight computer 6, connected in particular to the control means 5 of the device 1 by way of the link L6, is able to deliver control orders, by way of the links L7, for example to the actuators of the surfaces 8 for longitudinal control of the airplane AC (elevators, airbrakes) and/or to the engines 7 of said airplane, so as to apply the load factor values determined by the control means 5.
Schematically represented In
In the preferred realization, prior to the change-of-altitude maneuver, the pilots of the airplane AC determine a minimum execution deadline which is equal, for example, greater than the setpoint execution deadline, said setpoint deadline having been determined by the automatic pilot of the airplane AC and rendered accessible to the pilots by way, for example, of a control screen. The pilots furthermore determine a maximum execution deadline for the altitude capture phase so as to prevent the change-of-altitude maneuver from lasting too long.
Once the minimum and maximum execution deadlines have been determined by the pilots, the latter transmit them to the device 1, for example by means of an interface of keyboard type (not represented in
As a variant, these minimum and maximum execution deadlines can be defined by a definitive pre-established adjustment and transmitted directly, by way of the link L1, to the device 1.
The calculation means 2 of the device 1 are formed in such a way as to calculate the engagement level Ze on the basis of the following formula:
Ze=a−(Si+T)*Vzo
in which:
Depending on whether one seeks to reduce the number of RA alerts and/or of TA alerts, the threshold Si may be chosen equal respectively to the threshold SRA of RA alerts or to the threshold STA of TA alerts.
Furthermore, the determination means 3 are able to determine a modified vertical speed profile associated with said capture phase. A modified vertical speed profile such as this comprises a first part associated with a trajectory of the airplane AC of exponential type, followed by a second part associated with a trajectory of the airplane AC of parabolic type at 0.05g, completing the capture phase.
The expression modified vertical speed profile associated with the capture trajectory 11 is understood to mean a set of values of vertical speed corresponding to a set of altitude levels of the airplane AC along this trajectory 11.
Furthermore, the function f describing the modified vertical speed profile satisfies the following conditions:
in which
corresponds to the desired duration dcap of the capture phase.
Thus, when the airplane AC is climbing (
In the case where the airplane AC is descending (
Thus, assuming that the capture phase is completed at the instant Tcap equal to the mean (Tmin+Tmax)/2 (that is to say dcap=(dmin+dmax)/2), it is possible to use the following equation (obtained on the basis of the formula for dcap specified above) to determine the adjustment parameter a:
For performance reasons, the values of the parameter a obtained by solving this equation are preferably restricted to the interval [0; 300 m] (i.e. [0; 1000 feet]).
It should be noted that, when the airplane AC is descending (
Moreover, the control means 5 are activated by the activation means 4 when the following engagement conditions are simultaneously satisfied:
Once activated (the engagement conditions are realized), the control means 5 are able to engage the altitude capture phase.
Furthermore, these control means 5 determine the values of the load factor nz of the airplane AC along the capture trajectory 11 so as to transmit them to the flight computer 6, so that the vertical speed of said airplane AC at least approximately follows the modified vertical speed profile, previously determined by the determination means 3.
In the course of the capture phase, said load factor nz is of the proportional type and defined by the following formula:
nz=k*(Vz−f(Z))
in which:
On the basis of the load factor values received, the flight computer 6 can deliver control orders intended, for example, to control the actuators of the surfaces 8 for longitudinal control and/or the engines 7 of the airplane AC.
In the case where the setpoint altitude Zc is not reached before the end instant Tmax (for example because of turbulence), the mode of determining the load factor of the airplane AC is changed and becomes of proportional derivative type.
The load factor nz is then defined by the following formula:
nz=k1*Z−k2*Vz
in which k1 and k2 are negative constants whose values are determined by adjustment as a function of the characteristics of the airplane AC.
Number | Date | Country | Kind |
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08 05212 | Sep 2008 | FR | national |