The present invention relates to an electronic device for aiding with the piloting of an aircraft, the device comprising an acquisition module configured to acquire a current value of the roll angle of the aircraft, a computing module configured to compute at least one roll angle limit corresponding to a beginning of stalling of the aircraft, and a display module configured to display, on the screen, a first symbol indicating a current orientation of the aircraft.
The invention also relates to a method for aiding the piloting of an aircraft, the method being implemented by such an electronic device.
The invention also relates to a non-transitory computer-readable medium including a computer program, also called computer program product, including software instructions which, when they are implemented by a computer, carry out such a method.
The invention applies to the field of avionics, and more particularly to the field of systems for aiding with piloting relative to a stalling risk of the aircraft.
“Aircraft” refers to a moving vehicle piloted by at least one pilot, and in particular able to fly in the Earth's atmosphere, such as an airplane, a drone or a helicopter.
“Pilot” refers to a person piloting the aircraft from a cockpit situated in the aircraft or at a distance therefrom.
The pilot, through his piloting actions, acts on the attitude and roll, and it is therefore important for him to be able to be aware of the maneuvering margins with respect to stalling of the aircraft.
An electronic device and method of the aforementioned type are known from document U.S. Pat. No. 8,442,701 B2. This document describes a flight management method comprising, in response to a vertical maneuver of the aircraft, the identification of a roll angle limit by using a selected load factor to allow a vertical maneuvering capacity of the aircraft, and performing the vertical maneuvering of the aircraft by using said roll angle limit. The use of this roll angle limit seeks to avoid stalling of the aircraft, in particular during a low-speed lateral maneuver.
However, such a flight management method does not provide satisfactory aid to the pilot, the roll angle limit being directly taken into account by the flight management system to perform the maneuver of the aircraft.
The present invention aims to propose an electronic device and method for aiding with the piloting of an aircraft allowing the pilot to better anticipate a risk of stalling of the aircraft, while decreasing the cognitive load requested from the pilot, and then improving the flight safety.
To that end, the invention relates to an electronic device for aiding with the piloting of an aircraft, the device comprising:
wherein the computing module is further configured to compute at least one roll margin, each roll margin depending on a corresponding roll angle limit and the current value of the roll angle, and
wherein the display module is further configured, when the display condition is verified, to display, on the screen, at least one second symbol positioned relative to the first symbol, the deviation between each second symbol and the first symbol representing a respective roll margin.
According to other advantageous aspects of the invention, the piloting aid electronic device comprises one or more of the following features, considered alone or according to all technically possible combinations:
the characteristic value of the angle of attack being preferably an angle of attack limit corresponding to a beginning of stalling of the aircraft;
The invention also relates to a method for aiding with piloting of an aircraft, the method being implemented by an electronic device and comprising:
The invention also relates to a non-transitory computer-readable medium including a computer program including software instructions which, when implemented by computer equipment, carry out a method as defined above.
These features and advantages of the invention will appear more clearly upon reading the following description, provided solely as a non-limiting example, and done in reference to the appended drawings, in which:
In the example of
According to other examples, the aircraft 10 is an aircraft of another type, for example a corporate airplane or a military airplane, or a helicopter.
According to still another example, the aircraft 10 is a drone piloted remotely by a pilot from a piloting unit remote from the aircraft.
The “flight envelope” of an aircraft generally refers to a set of limitations/conditions applicable to the aircraft 10 guaranteeing its safe operation. Traditionally, these are conditions regarding the load factor, roll, angle of attack or speed of the aircraft 10.
“Stalling” refers to a loss, generally abrupt, of the lift of a carrying structure of the aircraft 10, such as a wing, the set of wings, a tail unit of the aircraft, or one or more rotor blades in the case of a helicopter. In case of stalling, the aircraft 10, which is no longer lifted enough (in part or in whole), generally becomes uncontrollable and loses altitude very quickly.
In the rest of the description, the notation a represents the angle of attack of the aircraft 10.
The angle of attack α is a critical parameter for piloting of the aircraft 10, and more particularly an angle of attack margin Δα relative to a stalling angle of attack. The stalling angle of attack is a parameter specific to the aircraft 10. The stalling angle of attack for example varies as a function of conditions related to the aircraft, such as its configuration (leading edge slat/tabs/gear), the state of its systems (engine, deicing, speed, mass, etc.) and outside conditions, for example the formation of ice on all or some of the airfoils.
Various causes may lead to a reduction in the angle of attack margin Δα with respect to stalling, for example a variation in air conditions (wind, turbulence), a variation in the load factor of the aircraft, or a variation of the roll φ of the aircraft.
In the rest of the description, the notation φ represents the roll angle of the aircraft 10, commonly called roll.
The aircraft 10 comprises an electronic device 14 for aiding with piloting, a guidance system 16 and a set of sensors 18 suitable for measuring various variables associated with the aircraft.
The electronic device for aiding with piloting 14 is able to provide a pilot of the aircraft 10 during piloting thereof, in particular via the display of relevant information with respect to a flight of the aircraft, in particular with information making it possible to alert the pilot of a risk of stalling of the aircraft 10.
As an optional addition, the electronic device for aiding with piloting 14 is also able to send the guidance system 16 said relevant information, in particular a roll angle limit φlim and a roll margin ΔφgΔ, φd, so that they may be taken into account by the guidance system 16.
The electronic device 14 for aiding with piloting is for example an onboard computer for example including a memory 30 and a processor 32 associated with the memory 30.
As an optional addition, the electronic device 14 for aiding with piloting further includes a display screen 34. In an alternative that is not shown, the display screen associated with the device for aiding with piloting 14 is a remote screen, which is not integrated into the piloting aid device 14, the display screen then for example being the screen of another piece of equipment or avionics system of the aircraft 10.
The guidance system 16 is, for example, an automatic pilot device 16, also called auto-flight control system (AFCS), also called automatic pilot (AP), or a flight management system (FMS) of the aircraft. Additionally, the guidance system is an auto-thrust device, not shown, also called automatic throttle. The automatic pilot device and/or the auto-thrust device are known in themselves, and make it possible to act on the trajectory of the aircraft. The flight management system is known in itself, and is suitable for managing a flight plan of the aircraft 10, from takeoff to landing.
The set of sensors 18 is configured in particular to measure variables associated with the movement of the aircraft 10, and to send the measured values of said variables in particular to the piloting aid device 14 and/or to the guidance system 16.
The sensors 18 are in particular suitable for providing information relative to the position of the aircraft 10, such as angles of attack, in particular the angle of attack α and the roll angle φ, accelerations, ground speed, route, altitude, latitude, longitude and/or relative to the environment of the aircraft 10, preferably relative to the atmosphere in which the aircraft 10 is moving, for example a pressure or a temperature.
The memory 30 is able to store a program 40 for acquiring a current value of the roll angle φ of the aircraft and a program 42 for computing at least one roll angle limit φlim corresponding to a beginning of stalling of the aircraft 10 and at least one roll margin Δφg, Δφd.
The memory 30 is also able to store a program 44 for displaying, on the screen 34, a first symbol indicating a current orientation of the aircraft, such as a speed vector symbol 50 or an artificial horizon line 60 or an airplane model, and furthermore, when a display condition is verified, at least one second symbol 52A, 52B positioned relative to the first symbol 50, 60, the deviation between each second symbol 52A, 52B and the first symbol 50, 60 and the respective roll margin Δφg, Δφd.
As an optional addition, the memory 30 is able to store a program 46 for sending the guidance system 16 the roll angle limit φlim and the roll margin Δφg, Δφd.
The processor 32 is configured to execute each of the programs 40, 42, 44, 46.
When executed by the processor 32, the acquisition program 40, the computing program 42, the display program 44, and optionally additionally the transmission program 46, respectively form an acquisition module configured to acquire the current value of the roll angle φ, a computing module configured to compute each roll angle limit φlim and each roll margin Δφg, Δφd, a display module configured to display, on the screen 34, the first symbol 50, 60 and furthermore, when the display condition is verified, each second symbol 52A, 52B, and optionally additionally a module for sending the guidance system 16 the roll angle limit φlim and the computed roll margin Δφg, Δφd.
Alternatively, the acquisition module 40, the computing module 42 and the display module 44 are made in the form of programmable logic components, such as one or more FPGA (Field-Programmable Gate Array), or in the form of dedicated integrated circuits of the ASIC (Application-Specific Integrated Circuit) type.
The acquisition module 40 is configured to acquire the current value of the roll angle φ of the aircraft 10, this current value for example being provided by the set of sensors 18.
As an optional addition, the acquisition module 40 is furthermore configured to acquire the current value of the angle of attack α of the aircraft 10, an angle of attack limit αlim, and a predefined zero lift angle of attack α0, and to send them to the computing module 42, to compute the or each roll angle limit φlim.
Alternatively or as an optional addition, the acquisition module 40 is configured to acquire, furthermore, a kinetic pressure applied to the aircraft 10, denoted (ρV2)/2, a lift gradient Czα specific to the aircraft 10 and the angle of attack limit αlim, and to send them to the computing module 42, in order to compute the or each roll angle limit φhm.
The computing module 42 is configured to compute at least one roll angle limit φlim corresponding to a beginning of stalling of the aircraft 10, and is further configured to compute at least one roll margin Δφg, Δφd, each roll margin Δφg, Δφd depending on the corresponding roll angle limit φhm and the current value of the roll angle φ.
Each roll margin Δφg, Δφd depends on a characteristic value of the angle of attack, said characteristic value of the angle of attack preferably being the angle of attack limit αlim corresponding to a beginning of stalling of the aircraft.
As an optional addition, the computing module 42 is further configured to compute several margins, i.e., a left roll margin Δφg and a right roll margin Δφd.
As previously indicated, the angle of attack α is a datum known in itself. Traditionally, the angle of attack α is a measurement available on board the aircraft 10, the latter for example being provided by the set of sensors 18.
Traditionally, different angle of attack limits are computed by alert systems, not shown, on board the aircraft 10, for example:
In the rest of the description, the angle of attack limit will be denoted αlim, this preferably being chosen from the aforementioned list of angle of attack limit values αnax, αprot, αSW, αstall, optionally with an additional margin or by combining two angle of attack limit values from the aforementioned list. The angle of attack limit αlim is preferably chosen to be equal to the maximum authorized angle of attack αmax.
Preferably, the angle of attack limit αlim optionally used to compute the roll angle φlim will be the same as that for the potential display of the angle of attack margin Δα with respect to the limit angle of attack.
The aircraft 10 for example verifies the following mechanical flight lift equation:
According to a first alternative, the roll angle limit φlim depends on a current value of the angle of attack α of the aircraft, the current value of the roll angle φ of the aircraft and the angle of attack limit αlim.
In particular, it is considered that in a balanced turn, the vertical component of the load factor verifies:
with φ the current value of the roll angle and θ the current value of the angle of lie.
From equations (1) and (2), considering a low θ and neglecting Fz (current hypothesis), one obtains the following equation:
Then considering the limit values from equation (3), one obtains the following equation:
The following equation is next obtained by combining equations (3) and (4):
The roll angle limit φlim then for example verifies the following equation:
According to the first alternative, the computing module 42 is then for example configured to compute the roll angle limit φlim according to equation (6) from the current value of the angle of attack α of the aircraft, the current value of the roll angle φ of the aircraft, the angle of attack limit αlim, and the predefined angle of attack with zero lift α0.
Additionally, the current value of the angle of attack α is computed as a function of one or more measured values of the angle of attack and an estimate of the time derivative of the angle of attack. The current value of the angle of attack is then denoted αhyb, corresponding to a hybridization of a measured value of the angle of attack and an estimate of the time derivative of the angle of attack.
The hybridized value of the angle of attack αhyb then for example verifies the following equation:
To compute an estimate of the time derivative d/dt(α) of the angle of attack, also denoted {dot over (α)}, the following force equilibrium equations on the longitudinal and vertical axes of the aircraft are for example used:
By further using the hypothesis of a zero constant sideslip (β=d\dt(β)=0), a constant airspeed, one obtains the following equation:
Furthermore, the longitudinal nx and vertical nz components of the load factor verify, by definition, following equations:
The estimate of the time derivative of the angle of attack {dot over (α)} then for example verifies the following equation:
According to this addition, the computing module 42 is then for example configured to compute the roll angle limit φlim according to equation (6) by using the hybridized value of the angle of attack αhyb, computed using equations (7) and (13), in place of the current value of the angle of attack α.
According to a second alternative, the roll angle limit φlim depends on a kinetic pressure applied to the aircraft, a lift gradient CZα specific to the aircraft and the angle of attack limit αlim.
The roll angle limit φlim then verifies, for example, the following equation, obtained from equation (4):
According to this second alternative, the computing module 42 is then for example configured to compute the roll angle limit φlim according to equation (14) from the kinetic pressure applied to the aircraft 10, the lift gradient CZα specific to the aircraft and the angle of attack limit αlim.
From the computed roll angle limit φlim, for example, according to one of the alternatives previously described, the computing module 42 is configured for the left roll margin Δφg corresponding to a decrease in the roll angle and the right roll margin Δφd corresponding to an increase in the roll angle.
The left roll margin Δφg and the right roll margin Δφd respectively verify the following equations:
Δφd=φlim−φ (15)
Δφg=φlim+φ (16)
As an optional addition, the computing module 42 is further configured to filter each computed roll margin Δφg, Δφd, for example using an order one low-pass filter with a time constant of about 100 ms.
The current value of the roll angle φ is an algebraic value, with the convention according to which this value is positive when the aircraft 10 performs a rotation on the right around its longitudinal axis and relative to its direction of advance, and negative when the aircraft 10 performs a rotation on the left.
The roll angle limit φlim is a positive value, and one skilled in the art will then understand that at least one roll margin Δφg, Δφd is equal to the difference between the roll angle limit φlim and the absolute value of the roll angle φ, this margin being the right roll margin Δφd when the current value of the roll angle φ is positive, or the left roll margin Δφg when the current value of the roll angle φ is negative.
As an optional addition, the computing module 42 is configured to compute, among the left roll margin Δφg and the right roll margin Δφd, only that which is equal to the difference between the roll angle limit φlim and the absolute value of the roll angle φ.
The display module 44 is configured to display, on the screen 34, the first symbol 50, 60 indicating a current orientation of the aircraft 10, and is further configured, when the display condition is verified, to display, on the screen 34, at least one second symbol 52A, 52B positioned relative to the first symbol 50, 60, the deviation between each second symbol 52A, 52B and the first symbol 50, 60 representing a respective roll margin Δφg, Δφd.
The display condition is verified in particular when the absolute value of the current value of the roll angle φ is above a predefined threshold. The predefined threshold for example has a value comprised between 40° and 50°, preferably equal to 45°. When the display condition is verified, the display module 44 is then configured to automatically display each second symbol 52A, 52B on the screen 34.
The display module 44 is for example configured to display a single second symbol 52A, 52B corresponding to the minimum roll margin among the left roll margin Δφg and the right roll margin Δφd, i.e., the roll margin equal to the difference between the roll angle limit φlim and the absolute value of the roll angle φ. The display module 44 is then configured to display either a second symbol 52A associated with the right roll margin Δφd, or a second symbol 52A associated with the left roll margin Δφg.
Alternatively, the display module 44 is configured to display two second symbols 52A, 52B, i.e., the second symbol 52A associated with the right roll margin Δφd and the second symbol 52A associated with the left roll margin Δφg, each one being positioned relative to the corresponding first symbol 50, 60.
As optional addition, the display module 44 is configured to display a third symbol 54 positioned relative to the first symbol formed by the speed vector symbol 50, the deviation between the third symbol 54 and the first symbol 50 representing the angle of attack margin Δα. The third symbol 54 is preferably connected to each displayed second symbol 52A, 52B.
The operation of the electronic piloting aid device 14 according to the invention will now be described using
During an initial step 100, performed regularly, the acquisition module 40 acquires the current value of the roll angle φ of the aircraft 10, and the computing module 42 computes the roll angle limit φlim corresponding to a beginning of stalling of the aircraft, for example, according to one of the alternatives previously described.
As an optional addition, the acquisition module 40 further acquires the current value of the angle of attack α of the aircraft 10, the angle of attack limit αlim, and the predefined zero lift angle of attack α0, and sends them to the computing module 42, to compute the roll angle limit φlim.
Alternatively, the acquisition module 40 further acquires the kinetic pressure (ρV2)/2 applied to the aircraft, the lift gradient CZα specific to the aircraft and the angle of attack limit αiim, and sends them to the computing module 42, to compute the roll angle limit φlim.
The computing module 42 next computes, during step 110, at least one roll margin Δφg, Δφd, using equation (15) and/or (16), each roll margin Δφg, Δφd depending on the roll angle limit φlim computed during step 100 and the current value of the roll angle φ acquired during step 100.
The display module 44 then displays, during a following step 120 and on the screen 34, a first symbol, such as the speed vector symbol 50 or the artificial horizon line 60, indicating the current orientation of the aircraft.
Furthermore, when the display condition is verified, the display module 44 displays, on the screen 34, at least one second symbol 52A, 52B positioned relative to the first symbol 50, 60, the deviation between each second symbol 52A, 52B and the first symbol 50, 60 representing a respective roll margin Δφg, Δφd.
According to a first example of the second symbols 52A, 52B, in
According to the first example, each roll margin Δφg, Δφd is shown in angular form between a corresponding wing of the speed vector symbol 50 and the bottom of the segment forming the corresponding second symbol 52A, 52B, as shown in
According to one optional additional aspect of this first example, the second symbol 52A, 52B corresponding to the minimum roll margin is further displayed with a segment having a thickness greater than that of the segment corresponding to the other second symbol 52A, 52B. In the example of
As previously indicated, the deviation between the third symbol 54 and the speed vector symbol 50 represents the angle of attack margin Δα, visible in
In the example of
The example of
According to a second example of the second symbol 52A, 52B, in
According to the second example, each roll margin Δφg, Δφd is shown in angular form between the corresponding wing of the speed vector symbol 50 and the segment forming the corresponding second symbol 52A, 52B, as shown in
The right roll margin Δφd is positive in the example of
One skilled in the art will observe that in the example of
The left roll margin Δφg is positive in the example of
As an optional addition, the deviation between the first symbol 54 and the speed vector symbol 50 represents the angle of attack margin Δα, visible in
According to a third example of the second symbols 52A, 52B, in
According to the third example, each roll margin Δφg, Δφd is shown in angular form between the horizon line 60 forming the first symbol and the segment forming the corresponding second symbol 52A, 52B, as shown in
A same example configuration of the aircraft 10 is shown three times in
As an optional addition, the deviation between the third symbol 54 and the speed vector symbol 50 represents the angle of attack margin Δα, shown in
In the example of
According to a fourth example of the two symbols 52A, 52B, in
According to this fourth example, each roll margin Δφg, Δφd is for represented in angular form between a pointer 62 representing the value of the roll angle φ on the roll diagram and the segment forming the corresponding second symbol 52A, 52B, as shown in
The right roll margin Δφd is positive in the example of
One skilled in the art will note that in the example of
As an optional addition, the crosshatched zones represent prohibited zones corresponding to stalling of the aircraft and in which the pointer 62 representing the value of the roll angle φ must not be found. The prohibited zone on the left is associated with the left roll margin Δφg and visible on the right in
The speed vector symbol 50 and the horizon line 60 are illustrated optionally in this fourth example.
According to a fifth example of the second symbols 52A, 52B, in
According to the fifth embodiment, each roll margin Δφg, Δφd is shown in the form of a distance between a corresponding wing of the speed vector symbol 50 and the tip of the arrow forming the corresponding second symbol 52A, 52B, as shown in
More specifically, the second symbol 52B of the left roll margin is shown in the form of an arrow on the left of the speed vector symbol 50, and oriented from left to right, and the left roll margin Δφg then corresponds to the distance between the tip of the arrow and the edge of the left wing of the speed vector symbol 50. The left roll margin Δφg is negative when the tip of the arrow forming the second symbol 52B has exceeded, from the left, the left edge of the speed vector symbol 50 in the direction corresponding to the wings of the speed vector symbol.
Similarly, the second symbol 52A of the right roll margin is shown in the form of an arrow on the right of the speed vector symbol 50, and oriented from right to left, and the right roll margin Δφd then corresponds to the distance between the tip of this arrow and the edge of the right wing of the speed vector symbol 50. The right roll margin Δφd is negative when the tip of the arrow forming the second symbol 52A has exceeded, from the right, the right edge of the speed vector symbol 50 in the direction corresponding to the wings of the speed vector symbol.
This illustration then allows the pilot to more easily see the side from which a risk of stalling of the aircraft 10 is arising.
The right roll margin Δφd is not shown in the example of
The horizon line 60 is illustrated optionally in this fifth example.
Thus, the electronic device 14 and method for aiding in the piloting an aircraft make it possible to display, when necessary, one or more roll margins Δφg, Δφd relative to a beginning of stalling of the aircraft 10, which give the pilot a relevant indication regarding a potential risk of stalling, while allowing him to easily assess the margin relative to this risk.
The electronic device 14 and the method for aiding in the piloting of an aircraft then help the pilot better anticipate a risk of stalling of the aircraft 10, while decreasing the cognitive load requested from the pilot, and therefore improving flight safety.
As an optional addition, each roll margin Δφg, Δφd depends on a characteristic value of the angle of attack, the characteristic value of the angle of attack preferably being at the angle of attack limit αlim corresponding to a beginning of stalling of the aircraft 10, which allows a more precise computation of each roll margin Δφg, Δφd.
Also as an optional addition, to compute the roll angle limit φlim, φlim_g, φlim_d, the current value of the angle of attack α is computed as a function of one or more measured values of the angle of attack and an estimate of the time derivative of the angle of attack, which makes it possible to have a more precise current value of the angle of attack α.
Furthermore, only one roll margin from among the left roll margin Δφg and the right roll margin Δφd is displayed, the displayed roll margin then being the most critical roll margin, which makes it possible to better focus the pilot's attention on the corrective action to be taken.
Also as an optional addition, the display condition is verified when the absolute value of the current value of the roll angle φ is above a predefined threshold, the display module 44 then being configured to automatically display each second symbol 52A, 52B on the screen. This then makes it possible to automatically display one or more additional indications for the pilot, i.e., the roll margin(s) Δφg, Δφd, only in a situation corresponding to a potential risk of stalling of the aircraft 10, and a contrario not to needlessly bother the pilot in a situation not corresponding to a potential stall of the aircraft 10.
According to a second embodiment, the computing module 42 is further configured to compute several roll angle limits, i.e., a left roll angle limit φiim_g and a right roll angle limit φiim_d.
According to the second embodiment, two current values, measured or estimated, of the angle of attack α are used, i.e., one for each side or direction of roll (left or right), i.e., a current left value of the roll angle αgauche and a current right value of the roll angle αdroit. On a fixed-wing aircraft, each angle of attack α represents the average angle of attack of one of the wings. The angle of attack of each wing is for example measured by using sensors 18 placed on each wing, or estimated by simply using an average angle of attack of the aircraft 10, also called global angle of attack.
To compute an estimate of the angle of attack of each wing from the average angle of attack of the aircraft 10, the roll rate and sideslip rate of the aircraft 10 are for example taken into account. Considering a wing element at a lateral distance L from the center of rotation of the aircraft 10, with V representing the airspeed, the angle of attack variation Δαρ generated by the rotation then verifies the equation:
The generated angle of attack variation Δαr then verifies the equation:
Thus, considering a characteristic or average value of the lateral distance L, this distance is specific to the aircraft, for example 10 m, and one obtains the correction to be applied to obtain the left and right angles of attack:
αdroite=α+(Δαp+Δαr) (19)
αgauche=α−(Δαp+Δαr) (20)
The computing module 42 is configured to compute the left roll angle limit φiim_g, for example using equation (6) according to the first alternative, by using the current left value of the roll angle αgauche in place of the current value of the roll angle α.
Similarly, the computing module 42 is configured to compute the right roll angle limit φiim_d, for example using equation (6) according to the first alternative, by using the current right value of the roll angle αdroit, in place of the current value of the roll angle α.
The left roll margin Δφg and the right roll margin Δφd respectively verify the following equations:
Δφd=φlim_d−φ (21)
Δφg=φlim_g+φ (22)
with φlim_d, φlim_g, φ respectively representing the computed left roll angle limit, the computed right roll angle limit, and the current value of the roll angle.
The computing module 42 is configured to compute each computed roll margin Δφg, Δφd, using equation (21) and/or (22).
As an optional addition, the computing module 42 is further configured to filter each computed roll margin Δφg, Δφd, for example using an order one low-pass filter with a time constant of about 100 ms.
The acquisition module 40 and the display module 44 according to this second embodiment are similar to those of the first embodiment previously described.
The operation of the piloting device 14 according to the second embodiment is then similar to that of the piloting a device 14 according the first embodiment, previously described, with the only difference that two roll angle limits are computed, whereas a single roll angle limit is computed in the first embodiment.
The advantages of the second embodiment comprise those of the first embodiment, and the piloting aid device 14 according to the second embodiment further makes it possible to compute the left roll margin Δφg and the right roll margin Δφd slightly more precisely, each roll margin Δφg, Δφd being computed from a dedicated roll angle limit.
One can thus see that the electronic device 14 and the method for aiding with the piloting of an aircraft allow the pilot to better anticipate a risk of stalling of the aircraft 10, while decreasing the cognitive load requested from the pilot, and then improving flight safety.
Number | Date | Country | Kind |
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15 01211 | Jun 2015 | FR | national |