IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0083496
(2006-10-12)
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등록번호 |
US-8393902
(2013-03-12)
|
우선권정보 |
EP-05447231 (2005-10-12) |
국제출원번호 |
PCT/EP2006/009841
(2006-10-12)
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§371/§102 date |
20080723
(20080723)
|
국제공개번호 |
WO2007/042290
(2007-04-19)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
10 |
초록
▼
The invention relates to a method to control the movements of a flight simulator involving linear and angular accelerations perceived at a pilot's seat and involving mathematical transformations of a lateral position y and a roll angle φ for said accelerations, wherein mathematical transformations a
The invention relates to a method to control the movements of a flight simulator involving linear and angular accelerations perceived at a pilot's seat and involving mathematical transformations of a lateral position y and a roll angle φ for said accelerations, wherein mathematical transformations are used with at least one of the following corrections: —Feed-forward of a specific force error due to the y-position wash-out into a roll angle transformation function; —Decomposition of specific force at pilot's position and addition of complementary filters to reproduce suitable side forces in the pilot's seat due to lateral accelerations; —Mathematical transformations linking a pilot's position in an aircraft and flight simulator to a motion base centroid.
대표청구항
▼
1. A method to control the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the at least two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular acceleration
1. A method to control the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the at least two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to the lateral position (y) and the roll angle (φ) of the simulator, and wherein the method comprises the step of: calculating the roll angle (φ) of the simulator due to simulated aircraft roll angle by correcting an originally calculated value (φhp) of the roll angle (φ) with a correction factor (φcor) proportional to a lateral specific force induced by a wash-out filter used during the earth gravity alignment calculation of the lateral position (y) of the simulator,wherein calculating the roll angle (φroll) of the simulator comprises using a mathematical transformation involving the feed-forward of a correction angle (φcor) in the roll angle transformation function according to the formulae: φcor=Ky·φhp−ÿroll/g φroll=φhp−φcor where φ-hp equals high pass filtered simulator roll angle, ÿ-roll equals lateral position acceleration of the pilots' reference point P, being the result of multiplying φ-hp with a gain Ky and g and then high pass filtering, g is the earth gravity constant, Ky is a gain lateral co-ordination factor, φ-roll equals the simulator roll angle as a result of simulated aircraft roll acceleration or roll rate. 2. The method according to claim 1, wherein in said mathematical transformation a lateral co-ordination factor Ky between 0 and 1 is introduced, allowing to reduce lateral travel at the expense of some acceptable spurious lateral specific force, by modulating between a ‘no co-ordination’ case whereby Ky=0 and a ‘full co-ordination’ case whereby Ky=1. 3. The method according to claim 2, wherein Ky=1, and the roll angle (φ-roll) is obtained by a 3rd or 4th order high-pass filter on simulated aircraft roll rate and lateral acceleration is at each time equal to this roll angle (φ-roll) multiplied by the earth acceleration (g). 4. The method according to claim 1, wherein the mathematical transformation involves a 2nd order roll angle (φ-roll) high pass filter and a 1st order y-washout filter, according to the transfer function formulae: [φhppltd]=PP2+2ξω0P+ω02[y¨roll/gφhp]=Ky·PP+1τ where pltd=input roll rate limited through a down tuning gain factor Kd, and optionally a roll rate limiting function, in such way that for a step in aileron command, the simulator lateral travel is of finite value, and where P stands for Laplace operator. 5. A method according to claim 1, wherein the mathematical transformation involves a 1st order roll angle high pass filter (φhp) and a 2nd order y-washout filter. 6. A computer program product comprising a non-transitory computer readable storage medium having machine-readable code stored thereon which, when executed by a processor of a computing device associated with a flight simulator simulating an aircraft, causes the processor to perform the step of the method as claimed in claim 1. 7. A method to control the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the at least two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to the lateral position (y) and the roll angle (φ) of the simulator, and wherein the method comprises the step of: decomposing the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; filtering the first component (Ay) through two filters, a high-pass filter and a low-pass filter;filtering each of the terms of the second component by a set of a first and a second complementary filters in parallel, complementary filters being filters whose sum of transfer functions is one; andusing the sum of the output of the high-pass filter and of the output of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and using the sum of the output of the low-pass filter and of the output of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ). 8. The method according to claim 7, wherein the second component of the specific force in the lateral direction is obtained by means of four additional filters: a first set of two complementary filters for roll acceleration and a second set of two complementary filters for yaw acceleration, in each set of complementary filters, one is commanding a simulator lateral excursion and the other commanding a simulator roll angle, according to the transfer function formulae: [yAyppltd]=-zpac·(P+2ξω1)P2+2ξω1P+ω12[φAyppltd]=zpacgω12·PP2+2ξω1P+ω12and[yAyrrltd]=xpac·P+2ξω2P2+2ξω2P+ω22[φAyrrltd]=-xpacg·ω22PP2+2ξω2P+ω22 where pltd and rltd are input roll and yaw rate respectively, limited through a down tuning gain factor Kp and Kr respectively, and optionally through a rate limiting function, and P stands for Laplace operator. 9. The method according to claim 7, wherein the fixed point of the simulated aircraft is the centre of gravity of said simulated aircraft. 10. A controller for controlling the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to the lateral position (y) and the roll angle (φ) of the simulator, said controller comprising: both (a) a first calculator configured to calculate the roll angle (φ) of the simulator due to simulated aircraft roll angle by correcting an originally calculated value (φhp) of the roll angle (φ) with a correction factor (φcor) proportional to a lateral specific force induced by a wash-out filter used during the earth gravity alignment calculation of the lateral position (y) of the simulator; and(b) a second calculator configured to decompose the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: AypilotAy+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; a high-pass filter and a low-pass filter for filtering the first component (Ay);two sets of a first and a second complementary filter, complementary filters being filters whose sum of transfer functions is one, for filtering each of the terms of the second component in parallel; anda combiner for combining the output of the high-pass filter and the outputs of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and a combiner for combining the output of the low-pass filter and the outputs of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ);or(b) a second calculator configured to decompose the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; a high-pass filter and a low-pass filter for filtering the first component (Ay);two sets of a first and a second complementary filter, complementary filters being filters whose sum of transfer functions is one, for filtering each of the terms of the second component in parallel; anda combiner for combining the output of the high-pass filter and the outputs of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and a combiner for combining the output of the low-pass filter and the outputs of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ). 11. A flight simulator motion system having a pilot's seat and at least two degrees of freedom, the two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the flight simulator is configured to perform controlled movements, involving linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to a lateral position (y) and a roll angle (φ) of the simulator, said flight simulator comprising: both (a) a first calculator configured to calculate the roll angle (φ) of the simulator due to simulated aircraft roll angle by correcting an originally calculated value (φhp) of the roll angle (φ) with a correction factor (φcor) proportional to a lateral specific force induced by a wash-out filter used during the earth gravity alignment calculation of the lateral position (y) of the simulator; and(b) a second calculator configured to decompose the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; a high-pass filter and a low-pass filter for filtering the first component (Ay); two sets of a first and a second complementary filter, complementary filters being filters whose sum of transfer functions is one, for filtering each of the terms of the second component in parallel; anda combiner for combining the output of the high-pass filter and the outputs of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and a combiner for combining the output of the low-pass filter and the outputs of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ);or(b) a second calculator configured to decompose the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; a high-pass filter and a low-pass filter for filtering the first component (Ay); two sets of a first and a second complementary filter, complementary filters being filters whose sum of transfer functions is one, for filtering each of the terms of the second component in parallel; anda combiner for combining the output of the high-pass filter and the outputs of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and a combiner for combining the output of the low-pass filter and the outputs of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ). 12. A method to control the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the at least two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to the lateral position (y) and the roll angle (φ) of the simulator, and wherein the method comprises the steps of: (a) calculating the roll angle (φ) of the simulator due to simulated aircraft roll angle by correcting an originally calculated value (φhp) of the roll angle (φ) with a correction factor (φcor) proportional to a lateral specific force induced by a wash-out filter used during the earth gravity alignment calculation of the lateral position (y) of the simulator; and(b) decomposing the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll φ) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; filtering the first component (Ay) through two filters, a high-pass filter and a low-pass filter;filtering each of the terms of the second component by a set of a first and a second complementary filters in parallel, complementary filters being filters whose sum of transfer functions is one; andusing the sum of the output of the high-pass filter and of the output of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and using the sum of the output of the low-pass filter and of the output of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ). 13. A method for compensating for a spurious lateral specific force of a flight simulator motion system having a roll angle (φ) and a lateral position (y), which is executed by a processor, comprising the steps of: receiving an originally calculated value (φhp) of the roll angle (φ); andcalculating the roll angle (φ) of the simulator due to simulated aircraft roll angle by correcting the originally calculated value (φhp) of the roll angle (φ) with a correction factor (φcor) proportional to a lateral specific force induced during the earth gravity alignment calculation of the lateral position (y) of the simulator,wherein calculating the roll angle (φroll) of the simulator comprises using a mathematical transformation involving the feed-forward of a correction angle (φcor) in the roll angle transformation function according to the formulae: φcor=Ky·φhp−ÿroll/g φroll=φhp−φcor where φ-hp equals high pass filtered simulator roll angle, ÿ-roll equals lateral position acceleration of the pilots' reference point P, being the result of multiplying φ-hp with a gain Ky and g and then high pass filtering, g is the earth gravity constant, Ky is a gain lateral co-ordination factor, φ-roll equals the simulator roll angle as a result of simulated aircraft roll acceleration or roll rate. 14. A non-transitory computer readable storage medium having machine-readable code stored thereon which, when executed by a processor of a computing device associated with a flight simulator simulating an aircraft, causes the processor to perform the steps of the method as claimed in claim 13. 15. A method for compensating for a lateral side force due to angular rotation of a flight simulator motion system having a roll angle (φ) and a lateral position (y), which is executed by a processor, comprising the steps of: decomposing a specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at a fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; filtering the first component (Ay) through two filters, a high-pass filter and a low-pass filter;filtering each of the terms of the second component by a set of a first and a second complementary filters in parallel, complementary filters being filters whose sum of transfer functions is one; andusing the sum of the output of the high-pass filter and of the output of the first of the complementary filters of each set to calculate the desired simulator lateral position (y), and using the sum of the output of the low-pass filter and of the output of the second of the complementary filters of each set to calculate the desired simulator roll angle (φ). 16. A non-transitory computer readable storage medium having machine-readable code stored thereon which, when executed by a processor of a computing device associated with a flight simulator simulating an aircraft, causes the processor to perform the steps of the method as claimed in claim 15. 17. A method to control the movements of a flight simulator motion system having a pilot's seat and at least two degrees of freedom, the at least two degrees of freedom including a lateral position (y) and a roll angle (φ), wherein the control of the movements involves linear and angular accelerations perceivable by a pilot seated at the pilot's seat, wherein roll rate (p) and yaw rate (r), as well as a specific force in a lateral direction (Ay) calculated according to a model of a simulated aircraft in a fixed point of the simulated aircraft are converted by a motion program to the lateral position (y) and the roll angle (φ) of the simulator, and wherein the method comprises the step of: decomposing the specific force in the lateral direction (Aypilot) acting at the pilot's reference point in the simulated aircraft into a first component and a second component, the first component relating to the specific force (Ay) at the fixed point of the simulated aircraft and the second component having a first term related to accelerations due to yaw (r) and a second term related to roll (p) angular accelerations, according to the formula: Aypilot=Ay+{dot over (r)}·xpac−{dot over (p)}·zpac xpac being the x coordinate of the pilot's reference point (P) in a reference system having an origin at the fixed point of the simulated aircraft and zpac being the z coordinate of the pilot's reference point in said reference system, {dot over (p)} being the roll angular acceleration and {dot over (r)} being the yaw angular acceleration; filtering the first component (Ay) through two filters, a high-pass filter and a low-pass filter;filtering each of the terms of the second component by a set of a first and a second filters in parallel; andusing the sum of the output of the high-pass filter and of the output of the first of the filters of each set to calculate the desired simulator lateral position (y), and using the sum of the output of the low-pass filter and of the output of the second of the filters of each set to calculate the desired simulator roll angle (φ).
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