FR2698691A1 - Inertial guidance system. - Google Patents

Abstract

An inertial guidance system has three accelerometers (AX, AY, AZ) enabling acceleration to be measured along three mutually perpendicular axes (X, Y, Z). An accelerometer (AZ) is placed at the reference point of the unit, the other two accelerometers being placed so that their centers of oscillations are coplanar with the first accelerometer, which makes it possible to reduce the complexity of the calculations necessary for the compensation of errors due to leverage effects. The deviations of the second accelerometer and of the third accelerometer with respect to the first accelerometer are preferably substantially equal and along appropriate axes, which further simplifies error compensation.

Description

The present invention relates to an inertial guidance system

incorporating accelerometers.

  Inertial guidance systems intended for vehicles such as aircraft have already been proposed, which have the function of determining the movement of a reference point (nominally fixed relative to the vehicle) relative to a certain navigation reference frame (for example local axes oriented

north, east and down).

  Inertial guidance systems always employ "accelerators"

  meters "which are sensors that can measure linear acceleration and they can use additional accelerometers or other sensors to determine

  angular movement, such as gyroscopes.

  In certain cases, it is ensured that, from the hardware point of view, the input axes of the accelerometers are maintained substantially in a fixed (or slowly variable) orientation relative to the navigation reference frame chosen. In such cases, the accelerometer output signals

  can be interpreted directly to give the movement of the vehicle.

  According to another possibility, the axes of the accelerometers are kept substantially aligned with the axes of the vehicle and therefore generally do not remain fixedly aligned with respect to the navigation reference frame chosen due to the rotations of the vehicle. These systems are called systems. "rigid"

  (i.e. without stabilized platform).

  In rigid systems, the movement of the reference point of the vehicle with respect to the navigation frame is calculated from the measurement of the movement, according to six degrees of freedom, of a single reference point which is fixed with respect to " 'set of inertial sensors' (denoted ISA), which designates the relatively rigid frame on which the motion sensors are mounted This point will hereinafter be called the ISA reference point We obtain the data defining the movement of the ISA reference point to from measurements made by accelerometers and any other motion sensor It is often convenient to

  define the vehicle reference point by the ISA reference point.

  It is often convenient to use a minimum of three accelerometers

  linear to a single axis and three gyroscopes to obtain the six necessary measurements

  to complete the definition of the movement of the reference point.

  However, it is generally not possible, from a material point of view, to have a group of three accelerometers with a single axis so that the points where the measurements are actually carried out by the three accelerometers (these points being here called the centers of the oscillations, or CP) coincide with the

ISA reference point.

  The fact that some accelerators may have their CP deviated from the reference point means that the linear movement they detect may differ from the true linear movement of the reference point Due to a lever effect, a purely angular movement around the ISA reference point can cause a linear acceleration to be present at the CP of one (or more) of the accelerometers, which leads to obtaining an ambiguous output signal These additional components are sometimes called "size effect" accelerations Since the hardware configuration of the accelerometers is known and the angular movement of the ISA reference point is detected, it is possible to calculate these size effects and introduce appropriate compensation into the output signal accelerometers When you cannot apply compensation for size effects with sufficient precision e t with sufficient speed to take account of the dynamic movement of the ISA reference point, this can lead, over time, to significant guidance errors. However, the calculations involved in compensating for the size effects for a group of three accelerometers can prove to be important, thus

  that the calculation errors of these compensation terms.

  The invention aims to optimize the hardware configuration of a set of inertial sensors designed for "rigid" applications and, therefore, to reduce the number of calculations which are necessary to compensate for size effects. According to the invention, an inertial guidance system is proposed, comprising three accelerometers A, AY, Az which are designed to measure the acceleration along three mutually perpendicular axes X, Y and Z, characterized in that the accelerometers are arranged so that their centers of oscillation are in a plane which comprises two of said axes, X and Y, and in that the center of the oscillations of the accelerometer Ax is not separated from the center of the oscillations of the accelerometer Az that along the direction of the Y axis, while the center of the oscillations of the accelerometer Ay is only moved away from the center of the oscillations of the accelerometer Az on the direction of the X axis.

  so that the amplitudes of the differences between Ax and Az and between Ay and Az are sensitive

definitely equal.

  It is preferred that the reference point ISA is placed within the material boundaries of the set of inertial sensors, or ISA In addition, it is preferred that the center of the oscillations of the accelerometer Az coincides with the point

ISA reference.

  Conveniently, the system has three gyroscopes, measuring

  each rotation relative to one, respective, of said three axes.

  According to one embodiment, the accelerometer A measures the acceleration along a nominally vertical axis, the accelerometers A and Ay measure

  acceleration along nominally horizontal axes.

  The invention finds a particular application in navigation units of the "rigid" type intended for use in aircraft and other vehicles.

  The following description, intended to illustrate the invention, aims

  to give a better understanding of its characteristics and advantages; it is based on the appended drawings, among which: FIG. 1 is a simplified representation which shows the effect of a

  single linear acceleration component combining with a single component

  health of angular movement on a sensor whose center of oscillation (CP) is moved away from a reference point; and FIG. 2 is a simplified representation of part of a rigid inertial guidance system Parts have been omitted in order to allow a

greater clarity.

  In the drawing of Figure 1, there is a point P around which the guide unit is substantially rotated, as shown in relation to a point Q, the rotation being indicated by an arrow c) The rotation existing at point Q which is induced by acceleration A is modified by the rotation of the body around point P As is well known, the linear acceleration at point Q, that is Aq, is, Aq = A + (r A) + ( r A o) A) (1) o cw is the angular velocity vector (with respect to the axes of inertia), is the speed of variation of w, r is the difference between P and Q, and

  A represents the vector multiplication operation.

  The measurement error of A due to the difference r is: E = Aq-A = (r A) + (r AC 0) A m (2) This is what is called the error d "'size effect", for which a

compensation is required.

  In a system using three single-axis accelerometers, the general error introduced into the output signal of each accelerator due to the size effect can be represented mathematically as follows: Ex = Rxx- (o) y 2 + C ) Z 2) + Rxy (+ () z + O) x O) y) Rxz (+ () y Ox O) z) (3) Ey = Ryy (Oax 2 + O) z Z) + Ryx (+ do ) z + (tx O) y) Ryz (+ 6) x C y) z) (4) Ez = Rzz (O) x 2 + O) y 2) + Rzx (+ () y + ax C Oz) Rzy (+,) x C z- y) (5) o Ex is the size effect error for the Ax accelerometer, Ey is the size effect error for the Ay accelerometer, Ez is l size effect error for the accelerometer Az, Rxx is the deviation of the center of the oscillations, or CP, of the accelerometer Ax from the reference point in the direction X, Rxy is the deviation of the CP from the accelerometer Ax with respect to the reference point in the direction Y, Rxz is the deviation of the CP of the accelerometer Ax with respect to the reference point in the direction Z, Ryx is the deviation of the CP of the accelerometer Ay from the reference point in the X direction, Ryy is the deviation of the CP of the accelerometer Ay from the reference point in the Y direction, Ryz is the deviation of the CP of the accelerometer Ay with respect to the reference point in the direction Z, Rzx is the deviation of the CP of the accelerometer Az from the reference point in the direction X, Rzy is the deviation of the CP of the accelerometer Az with respect to the reference point in the direction Y, Rzz is the deviation of the CP of the accelerometer Az with respect to the reference point in the direction Z, oe) is the angular velocity component of the ISA with respect at the X axis, o) y is the angular velocity component of the ISA with respect to the Y axis, oe, is the angular velocity component of the ISA with respect to the Z axis, We will have understood that the calculations necessary to carry out this general compensation are important, because they involve nir at least different multiplications and 15 different additions or subtractions In addition, it is often appropriate to estimate the terms of angular acceleration by making the difference between successive angular velocity measurements Three similar terms are generally necessary The invention aims to reduce the complexity of the

error correction.

  The unit shown in Figure 2 comprises a housing 1, which is shown partially cut out The housing 1 is fixed to the floor 2 of an aircraft by means of anti-vibration mounting elements 3 The aircraft has six degrees of freedom of movement, namely translation and rotation relative to

  each of the three axes X, Y and Z In the context of this description, the X axis is

  taken as the longitudinal horizontal axis, or "roll" axis, the X axis is the lateral horizontal axis, or "pitch" axis, and the Z axis is the vertical axis, or "yaw" axis To control movements relative to each axis, the unit has three gyroscopes (not shown) which control rotation relative to the axes and

  three accelerometers Ax, Ay and A used to measure the translation along the axes.

  Each accelerometer has a center of oscillations, designated by P in the figure, which is the important point to consider when deciding on positioning.

accelerometers.

  To reduce the necessary compensation, an accelerometer is placed, in this case the accelerometer Az so that its center of oscillations P coincides with the reference point D of the unit Thus, no compensation is necessary for this accelerometer, at know the vertical accelerometer So that the effect associated with the Z axis can be removed in the horizontal accelerometers Ax and Ay, we arrange these so that they are coplanar with Az in the X and Y plane. provision then only imposes compensation along the axes X and Y, and this compensation is further simplified if one makes sure that each of the accelerometers Ax and Ay are separated from Az by the same quantity, namely r De

  therefore, the compensation required in each case is very similar.

  We can show this mathematically by making the following substitutions In equation (5), we carry Rzx = Rzy = Rzz = 0, which gives for the error Ez: Ez = 0 (6) In equation (4) , we carry Ryx = r; Ryy = Ryz = 0, which gives for the error Ey: Ey = -r dz + r o) x oy (7) Finally, in equation (3), we carry Rxy = r; Rxx = Rxz = 0, which gives for the error Ex Ex = r oz + r- x y (8) Thus, the calculations necessary for the compensation have been reduced to

  3 different multiplications (r o z, r cox and (r ox) oy) and 2 additions (or subtrac-

tions).

  In this case, only one angular acceleration term bz is necessary.

  It will be understood that, while the preferred arrangement eliminates the compensation relating to the Z axis, any arrangement placing all the accelerometers in a plane containing two axes will simplify the compensation, since two cases

  only should be considered to them.

  The gyroscopes contained in the unit do not require any compensation.

  tion because they do not experience leverage.

  Of course, those skilled in the art will be able to imagine, from the

  system whose description has just been given by way of illustration only and

  in no way limiting, various variants and modifications not departing from the scope of the invention.

Claims (7)

  1 Inertial guidance system, comprising three accelerometers (Ax, Ay, Az) which are intended to measure the acceleration along three mutually perpendicular axes (X, Y, Z), characterized in that the accelerometers are arranged so that their centers oscillations are in a plane which contains two of said axes, and in that a first accelerometer is moved away from a second accelerometer along the direction of the first of said two axes, while a third accelerometer is moved away from the first accelerometer along direction of second of said two axes.   2 System according to claim 1, characterized in that the differences between the first and the second accelerometer and between the first and the third   accelerometers are designed to be substantially equal.   3 System according to claim 1 or 2, characterized in that it comprises a reference point with respect to which the movement is measured, this   point within the physical boundaries of the system.   4 System according to claim 3, characterized in that the center of   oscillations of the first accelerometer coincides with the reference point.   System according to any one of claims 1 to 4, characterized   in that it also has three gyroscopes, each of which measures the rotation   with respect to one, different, of said three axes.   6 System according to any one of claims 1 to 5, characterized   in that the first accelerometer measures the acceleration along a nominal axis-   vertical, the second and third accelerometers measuring the acceleration   along nominally horizontal axes.   7 Rigid type navigation system, characterized in that it   comprises an inertial guidance system according to any one of the claims 1 to 6.   8 aircraft navigation system, characterized in that it comprises a   system as described in any one of claims 1 to 7.