GB1605424A - Apparatus for directing a mobile craft to a rendezvous with another mobile craft - Google Patents

Description

(54) APPARATUS FOR DIRECTING A MOBILE CRAFT TO A RENDEZVOUS WrNHANOTHER MOBILE CRAFT I, Secretary of State for Defence, London, do hereby declare the invention for which Spray that a patent may be granted to me, and the method by which it is to be performed, to be particularly described in and by the following statement: The present invention relates to apparatus for guiding a first mobile craft to a meeting with a second mobile craft. In this specification the term 'mobile craft' should be interpreted widely so as to include any kind of aircraft, spacecraft, or guided missile. The apparatus may for instance be used to guide a defensive missile to intercept an attacking missile, or to guide a space craft towards a space station or mother craft.

It is known that a defensive missile may be guided towards an attacking craft by control signals derived from measurements of a linesf-sight from a control point to the attacking craft. To avoid confusion the attacking craft will hereinafter be called the target. The line-of-sight may be established by visible light, infra-red light, radar signals, or any other form of radiation which can be projected along a measurable straight-line axis which will be moved either manually or automatically so that it always points towards the target, by apparatus incorporating means for deriving signals ba representing a rate of rotation 6 of the line-of sight. It is known also to derive signals representing the displacement ~ of the missile from the line-of-sight, the range Rn: from the control point to the missile, and its rate of change Rm, and to derive from these signals a control signal representing the quantity fO + RmOc + 2RmOc where fl is a predetermined function of e, Oc is derived from ea by a simple smoothing circuit and the term Oc (which represents the rate of change of Oc) is derived from Oc by a simple differentiating circuit. This control signal is used to govern an acceleration applied to the missile transverse to the line-of-sight so as to increase the accuracy of the rendezvous or the chance of meeting with the target.

It is also known that mobile craft are often guided towards a specified destination by a technique called proportional navigation, in which the flight direction of the craft is made to rotate at a rate k times the rate of rotation of a sight-line from the craft to its destination where k has a predetermined value. In one form of proportional navigation the craft follows a circular arc to its destination.

It is an object of the invention to provide apparatus for guiding a first mobile craft towards a rendezvous or meeting with a second mobile craft which improves the above-mentioned smoothing and differentiation by making use of the assumption or knowledge that the second craft is being guided along a circular arc. This includes as a special case the case of a craft being guided to a system wherein k = 2 along a circular arc towards a control point.

According to the present invention there is provided apparatus for directing a first mobile craft to a rendezvous with a second mobile craft which is being guided towards a control point, comprising:- tracking means for establishing a line-of-sight between the control point and the second mobile craft and tracking the said line-of-sight to follow the said second mobile craft and deriving a signal 0a representing the rate of rotation o of the said line-of-sight about the control point; monitoring means for deriving a displacement signal representing the displacement e of the first mobile craft from the said line-of-sight, a first range signal representing the range Rn: from the control point to the first mobile craft, and a first range rate signal representing the rate of change Rm of the range Rm; ranging means for deriving a second range signal representing the range R1 from the control point to the second mobile craft, and a second range rate signal representing the rate of change R, of the range Rt; computing means responsive to the signal representing ba for deriving representations of quantities Oc, bc, ic which will tend to become consistent with the equations B, = -20% - 30c ( ,/R,) and

and also to minimise the difference

the symbol

indicating integration with respect to time; control means for deriving the aforesaid representations a control signal representing a quantity fO+Rmbc+2Rmbc wherein ft) is a predetermined function of; and guidance means for causing the first said mobile craft to develop an acceleration transverse to the said line-of-sight, of a magnitude dependent on the said control signal.

The computing means may be a stochastic controller operating according to the novel equation which relates the quantities ec, ec, 0 as hereinbefore specified.

A stochastic controller is an equipment for controlling a process in response to estimates or measurements of control parameters which are subject to significant random errors, and is therefore constructed to revise and update signals representing its control parameters by applying the latest available estimates or measurements to a mathematical model which tends to make the control parameters consistent with assumed mathematical inter-relationships, in addition to controlling the process as desired in response to the current values of its control parameter signals. This is explained for instance by OL.R. Jacobs in his book "Introduction to Control Theory" (Clarendon Press 1974), pages 276 & 334 et seq.

The first mobile craft may be a missile or rocket, in which case the signals representing Rm and Am may be derived from a measurement of the time elapsed since the missile or rocket was launched and a knowledge of the characteristics of its type assuming that its performance will be typical of its kind. The displacement e must be measured; this may be done by various available known techniques.

An embodiment of the invention will now be described by way of example only, with reference to the drawings accompanying the provisional specification of which: Figure 1 is a sketch showing the geometrical relationship of some of the quantities involved in a guidance operation, and Figure 2 is a schematic block diagram of a general form of guidance apparatus.

In Figure 1, T represents the instantaneous position of a mobile craft which is being guides along a circular arc towards a control point P which may or may not coincide with a control point P. M represents the instantaneous position of another mobile craft which has been launched from P and is to be guided to a meeting with the craft now at T.

At the control point P, the angle between the sight line PT and a stable reference direction is represented by the symbol 0. The rate of rotation O of the sight line PT (which is the rate of change of 0) is measured. The instantaneous range of the craft now at M from the control point P (i.e. the distance MP) is represented by the symbol Rnr and the displacement of the craft M from the sight line PT is represented by the symbol e. In practice e may be deduced from a measurement of the angle MPT and a knowledge of the range Rm. In this situation it can be shown that the derivatives e, o and 8 should satisfy the equation ≈= -203 - 30(R,/R,) where Rr is the instantaneous range of the craft at T from the control point P and Rt is its rate of change.

Figure 2 shows apparatus which utilises this fact. In the following description the symbol 0 is used with a suffix a to indicate an actual measured value, and with a suffix ç to indicate a calculated or estimated value. A tracking apparatus 1 provides signals Oa, Rr and Rt which are applied to analogue computing apparatus arranged as a stochastic controller. This comprises analogue signal combiners 3,4 and 5, analogue signal weighting units 6 and 7, integrators 9 and 10, and analogue signal computing networks 12 and 13 arranged as shown. The signs + and - adjacent to the inputs of the combiner 3 indicate that it derives a signal representing the difference (6a-c) of the quantities represented by the signals applied to it.

The other combiners 4 and 5 combine their input signals additively. The computing network 12 is connected to receive an input representing e and to derive an output representing -203C. The computing network 13 is connected to receive inputs representing Oc, Rt and Rt and to derive an output representing the function -30C(R,/R,).

These units 3 to 14 are each constructed according to conventional techniques of the analogue computing art. The weighting units 6 and 7 are adjusted, following the techniques described for instance in 'Applied Optimal Control' by A E Bryson and Y C Ho, (Blaisdell Publishing Co 1969) at p 425 et seq so that the whole combination (units 3 to 14) will operate as a stochastic controller to derive signals which tend to become consistent with the equations

and minimise the difference ea - Oc (that is to say also making Oc follow a). This provides a signal representing bc which may be taken as a good approximation to a and is derived by a process which improves the differentiation and can be made satisfactorily stable and comparatively free from noise.

A timer 15 is connected to receive a launch timing signal from launching apparatus (not shown) and to provide a signal representing , the time elapsed since launching of the craft M in Figure 1. A range characteristic unit 16 receives the t signal and derives signals representing fJ(t) = Rm andfi(t) = Rm according to stored characteristics relevant to the type of the craft M; the elapsed time is represented digitally and the unit 16 is a digital computer store loaded with values of f'(fland f2(t) in addresses which are values oft. The unit 16 converts the stored values to analogue form. An analogue multiplier 17 is connected to receive the Rm signal from unit 16 and the 8c signal from the integrator 10 and to form a representation of the product Rmoc.

Another analogue multiplier 18 is connected to receive the Am signal from unit 16 and the Oc signal from the integrator 9 and to form a representation of the product 2RmOC. A displacement signal unit 19 derives a signal representing e and an analogue computing network 20 derives a representation of a function fl; these units and the function ft are arrangements well known in the guidance art.

Outputs from the units 17. 18 and 20 are additively combined in an analogue combiner 21 to form a control signal which is applied to conventional guidance apparatus 22, which will include means for sending control signals to the craft M.

Various modifications are possible. Clearly various parts of all of the calculations could be done by digital rather than analogue techniques, and the tracking apparatus may be constructed to provide a signal representing the quotient Xt/Rt instead of separate representations of Rt and1.

WHAT I CLAIM IS: 1. Apparatus for directing a first mobile craft to a rendezvous with a second mobile craft which is being guided along a circular arcuate path, comprising:- tracking means for establishing a line-of-sight between a control point and the second mobile craft and tracking the said line-of-sight to follow the said second mobile craft and deriving a signal ea representing the rate of rotation 4 of the said line-of-sight about the control point; monitoring means for deriving a displacement signal representing the displacement of the first mobile craft from the said line-of-sight, a first range signal representing the range Rm from the control point to the first mobile craft, and a first range rate signal representing the rate of change Am of the range Rm; ranging means for deriving a second range signal representing the range R1 from the control point to the first mobile craft, and a first range rate signal representing the rate of change A,n of the range Rm; ranging means for deriving a second range signal representing the range R, from the control point to the second mobile craft, and a second range rate signal representing the rate of change Rt of the range R1; computing means responsive to the signal representing ba for deriving representations of quantities bc, Oc, bc which will tend to become consistent with the equations

and also to minimise the difference

the symbol

indicating integration with respect to time; control means for deriving from the aforesaid representations a control signal representing a quantity j() + Rmoc + 2Rmec wherein jLe) is a predetermined function of e; and, guidance means for causing the said first mobile craft to develop an acceleration transverse to the said line-of-sight, of a magnitude dependant on the said control signal.

2. Apparatus as claimed in claim 1 wherein the computing means is a stochastic controller operating according to the novel equation which relates the quantities bcs ÛC, bc, Rt and Rt as set

Claims (1)

1. out in claim 1.

   3. Apparatus as claimed in claim 1 specifically for use in circumstances where the first mobile craft is a missile or rocket of a known type, and wherein the monitoring means is arranged to derive signals Rm and A,n from a measurement of the time elapsed since the missile or rocket was launched and from parameters stored in the apparatus representing known performance characteristics of that type of rocket or missile.

   4. Apparatus as claimed in claim 1 and substantially as hereinbefore described with reference to Figures 1 and 2 of the drawings accompanying the provisional specification.