The Design of Finite-time Convergence Guidance Law for Head

Pursuit based on Adaptive Sliding Mode Control

Cheng Zhang

1,2

, Ke Zhang

1,2

and Jingyu Wang

1,2

School of Astronautics, Northwestern Polytechnical University, Xi’an 710072, China

National Key Laboratory of Aerospace Flight Dynamics, Northwestern Polytechnical University, Xi’an 710072, China

Keywords: Finite-time Convergence, Head Pursuit, Terminal Sliding Mode, Sliding Mode Control.

Abstract: The high-speed target interception plays a vital role in the modern industry with many application scenarios.

Due to the difficulties of direct interception in high speed, the head pursuit intercept is frequently considered

for the target of re-entering flight vehicle. In this paper, a novel terminal sliding mode control method is

proposed for the interception of high-speed maneuvering target, in which the finite convergence guidance

law is initially designed under the constraint of intercept angle. By introducing the mathematical model of

correlative motion between interceptor and target, the sliding surface is researched and designed to meet the

critical conditions of head pursuit intercepting. Meanwhile, considering the dynamic characteristics of both

interceptor and target, an adaptive guidance law is therefore proposed to compensate the modelling errors,

which goal is to improve the accuracy of interception. The stability analysis is theoretically proved in terms

of the Lyapunov method. Numerical simulations are presented to validate the robustness and effectiveness

of the proposed guidance law, by which good intercepting performance can be supported.

1 INTRODUCTION

In recent years, high-speed targets such as re-

entering flight vehicle have brought severe

challenges to the traditional interception system.

Hypersonic vehicle target requires higher accuracy

of the interception system, such as long distance

target detection, the quick response of each

subsystem in the system, the ability to withstand

high temperature of seeker and the ability of the

guidance system to adapt to harsh aerodynamic

environment interference and so on.

Generally speaking, the requirement for the

speed of interceptor is higher than the target in the

terminal interception process, it is therefore not very

suitable for the traditional rear-end interception issue.

However, considering the head-on interception, due

to the extreme high speed of the target, it will cause

the missile - target relative speed become very large.

Therefore, it will cause more stringent requirements

to the computation capacity of the computer as well

as other hardware devices on-board. Since all these

requirements cannot be achieved in a very short time,

the designing of appropriate control method will be

a practically realizable way.

To solve the problem of interception in the high

speed situation, the head pursuit(HP) interception is

proposed (Shima, 2007). By using the HP

interception, not only the seeker can be protected

from the vital influence of high temperature and bad

aerodynamic interference, but also the energy

consumption of the interceptor can be reduced.

Therefore, the research of HP interception has

attracted huge attention in recent years.

As a frequently used design method in control

system, the flexibility of sliding mode control (SMC)

is strong. As the dynamic characteristic of a control

system is related to the designed sliding surface, so

when the control system is running on a specifically

designed sliding surface, the quality of which will

significantly affect the performance of the system.

In fact, as long as the system is assured to finally

approach the sliding surface and satisfy the stability

condition, there will be no limit to the form of used

sliding surface. Therefore, how to design a sliding

surface with better control performance has become

the focus of research, from which also derived a lot

of new SMC methods (Goyal, 2015). However,

traditional SMC approaches generally use the linear

sliding surface, thus the system is only asymptotic

convergence in this case. If the target is with

complex non-linearity property, good control

110

Zhang, C., Zhang, K. and Wang, J.

The Design of Finite-time Convergence Guidance Law for Head Pursuit based on Adaptive Sliding Mode Control.

DOI: 10.5220/0005987701100118

In Proceedings of the 13th International Conference on Informatics in Control, Automation and Robotics (ICINCO 2016) - Volume 2, pages 110-118

ISBN: 978-989-758-198-4

performance cannot be achieved by applying the

traditional method or even worse, the stability of

system cannot be guaranteed. However, a terminal

sliding mode (TSM) control method that can

converge to zero in finite time is initially proposed

in (Zhihong, 1994), which has opened up a new

research field of SMC. Thereafter, the TSM based

control method has become one of the hot topics in

the research of SMC (Feng, 2013 and Kumar, 2014).

2 RELATED WORKS

In the research of sliding mode control method, the

essential key is to design the guidance law. Due to

the fact that relative motion equations of target and

interceptor have strong nonlinear cross coupling,

parameter uncertainty and external disturbance

inevitably exist, so the target interception system is a

nonlinear uncertain system.

To deal with the control issue of this complex

system, many research methods have been proposed

in recent years. In the research works of (Liu, 2010

and Li, 2011), two control methods are presented to

solve the control problem of the classic SISO and

MIMO nonlinear system, in which the variable

structure control and fuzzy control theory are used

respectively. Though the achieved results have

shown that good outputs can be obtained by

applying the proposed methods, the target systems

that considered in these works are simple.

Regarding the control problem of the complex

system in real world, a fuzzy terminal sliding mode

control strategy is proposed in (Gu, 2015) for the

control of marine current power system. The

proposed control strategy mainly consists of two

major parts, which are a fuzzy logic controller for

deriving the reference generator current and a non-

singular terminal sliding mode controller to track the

aforementioned derived current, respectively.

Meanwhile, in the work of (Zhao, 2015), an output

feedback terminal sliding mode control framework

for the continuous stirred tank reactor is presented.

In this work, two novel control algorithms of TSM

are studied, of which the theoretical stability

analysis is given. The experimental results of above-

mentioned works show that, if appropriate designed,

the TSM based control approaches can be effective

solutions to deal with the nonlinear system, while its

robustness to external disturbance is superior to the

traditional research works. However, the high-speed

target is a highly nonlinear system which far more

complex than the system considered in the industrial

application scenario. Therefore, the presented works

have obvious limitations and thus cannot be applied

on the interception, which bring out the requirement

of novel control method.

In the work of (Behera, 2015), the steady-state

behaviour of discretized TSM control is

comprehensively studied, in which the continuous-

time system is discretized and the analysis of steady-

state behaviour is given in the terms of periodic

orbits. By finding all possible orbits, the research

reveals that only period-2 orbit is satisfied by the

state evolution and thus retained in steady-state.

Though the analytic result is achieved by only

considering a second-order system, it can be

developed for a nth order SISO system as well. This

work shows that the continuous-time system can be

theoretically researched by conducting a discretized

processing, which supports promising application in

the design of TSM control method for higher order

nonlinear complex system. Moreover, a non-singular

TSM controller is proposed for actuated exoskeleton

in (Madani, 2015), of which the target system is

actually an active orthosis used for rehabilitation

purpose. Since the system has a complex dynamical

model with no prior knowledge, the proposed

controller uses non-singular TSM technique to

obtain the expected good performance in terms of

convergence in a finite time. Supported by the

theoretical stability proof in closed loop, the

proposed approach is ensured to be stable according

to the Lyapunov formalism. Experimental results

have shown that smooth movements could be

conducted for flexion and extension, which indicates

the potential application in real world. However, it

should be pointed out that, the system considered in

this work is still not as complex as the target system

considered in the interception scenario, which shows

that improvement of previous proposed approaches

should be researched.

Considering the specific control target system of

spacecraft, a SMC approach is designed in (Lu,

2012), in which the existence of external

disturbances and inertia uncertainties are both taken

into account. The simulation results show that, the

proposed approach is capable to achieve the goal of

effectively tracking on the attitude of a spacecraft.

Meanwhile, a novel adaptive sliding mode control

scheme for spacecraft body-fixed hovering in the

proximity of an asteroid is proposed in (Lee, 2015).

Since the bounds of parametric uncertainties as well

as the disturbances are not required in advance, the

scheme is proposed to guarantee the asymptotic

stability of states for both position and attitude

stabilization. The achieved results of numerical

simulation have demonstrated both low control

The Design of Finite-time Convergence Guidance Law for Head Pursuit based on Adaptive Sliding Mode Control

111

inputs and effectiveness of control strategy. Though

both of these works have shown that sliding mode

control method is a practically useful tool for the

control issue of spacecraft, the targets considered in

these systems are regular spacecraft with normal

speed, which cause the limitations when apply them

on the HP interception problem.

Particularly, a HP sliding mode variable structure

guidance law is introduced in the work of (Hua,

2011), in which the deviation and related derivative

are used as switching function by using the

Lyapunov method. Although it can obtain better

results for the case of high-speed interception, much

more information of the system is required, which is

difficult to achieve. The research work accomplished

in (Song, 2015) is similar to our work, in which the

design of a guidance law for non-decoupling 3D

engagement geometry is studied. By using finite

time integral sliding mode manifold, an improved

control law is developed to estimate the upper bound

of the target acceleration. Experiment results show

that, the proposed control method can control the

target in both constant speed and varying speed

situations effectively. However, despite that the

target can be precisely intercepted by applying the

proposed method, the designed control laws are

specifically developed regarding the classic way of

interception which is different from HP interception.

Consequently, novel control method for the HP

interception system should be theoretically studied.

In this paper, by considering the target maneuvering

as bounded uncertain item of the system, an adaptive

sliding mode guidance law suitable for head pursuit

interception scenario is proposed. The derivation of

the designed guidance law is based on the dynamic

characteristics of both interceptor and target, while

their model errors are taken into account as well.

The stability analysis of the proposed TSM adaptive

control method is studied by providing the detailed

theoretically proof. Finally, simulation experiments

show that robustness and convergence in finite time

could be achieved for the HP interception.

3 OVERVIEW OF HEAD

PURSUIT INTERCEPTION

3.1 HP Working Process

The schematic diagram is shown in Figure 1. In

general, the head pursuit intercept can be divided

into three phases: a) approach; b) control the orbit

direction of interceptor to enter the preset orbit at a

predetermined time; c) terminal guidance.

The major task of interception in the terminal

process is to adjust the position as well as direction

of the interceptor flight errors, while making the tail

of interceptor as close as to the target, then intercept

the target head.

Figure 1: Head pursuit interception.

3.2 HP Kinematic Equation

In the stage of the terminal guidance, the interceptor

will fly in the same general direction as the target,

while ahead of it at a lower speed. Because of the

relatively short interception time and the overload

restriction, the interceptor fight direction will rarely

change. As a result, the interception process can be

decoupled into two orthogonal planes, which are

vertical plane and horizontal plane respectively.

Correspondingly, the expected guidance law can be

designed in the two planes.

To simplify the problem of HP interception, we

assume that the interceptor and the target can be

treated as a particle. The acceleration vectors of both

interceptor and target are vertical with their velocity

vector, thus the acceleration vector will only change

the velocity of the interceptor and target, while the

direction will not change.

Considering the case in the longitudinal plane as

an example, the planar geometry is shown in Figure

2. It can be seen that, the target

is located behind

the interceptor

which has lower speed. Here, the

speed, maneuvring acceleration and flight-path angle

are respectively denoted by

, a and



. The range

between the target and interceptor is defined as

while

is the line of sight (LOS) angle relative to a

fixed reference. Meanwhile, the angles



and



are

the instantaneous target and interceptor direction of

flight relative to the LOS.

In Figure 2, the

denotes the relative speed

between the interceptor and target, which is defined

ICINCO 2016 - 13th International Conference on Informatics in Control, Automation and Robotics

112

cos cos

rI T

VV V







(1)

and the speed perpendicular to the LOS is

sin sin

qI T

VV V







(2)

















Figure 2: HP geometry.

Therefore, we can have the equations of HP

interception as follows

cos cos

rI T

TT q

II q

rV V V

aV Vr

aV V r

qVr







 





















(3)

Meanwhile, the speeds of interceptor and target

are represented by

and

, respectively. Thus,

the speeds should be constant and non-dimensional

parameter

can be defined as the speed ratio as

KVV

(4)

Let the running time is

, the terminal guidance

initials at

0t 

with

(t 0) 0r







and terminates at

tt

where

 



arg 0

trtrt



(5)

Considering the goal of successfully intercept,

the conditions that must be met are as follow





lim 0





(6)

lim 0





















(7)

The purpose of HP guidance control is to guide

the interceptor to the point that satisfies the

conditions of Eq.(6) and Eq.(7). Therefore, the

angles



and



need to be proportionally changed

during the design process







(8)

where n is guidance coefficient.

Nevertheless, if in the real interception scenario,

the interceptor might need to hit the target with a

certain angle which brings more requirements to the

designed control law. Therefore, it is quite necessary

to put forward a more objective terminal interception

geometric condition, thus the Eq. (8) is amended as









 

(9)

where 2





 is selected purposely and





sin sin















(10)

4 PROPOSED APPROACH

At the very beginning of the design of guidance law,

we should determine the dynamic of the interceptor

and target, and then we use the TSM control to

design the guidance law, finally prove the stability.

In order to compensate the interference of both

model errors and external disturbances, the finite

time convergence adaptive reaching law is designed,

the design method is based on the following three

steps: First, select the proper sliding surface. Second,

design the adaptive guidance law. Finally, prove the

stability of both processes in either reaching phase

or in sliding phase.

4.1 Dynamic

Though Eq.(9) describes the geometric rule between

the interceptor and target, the explicit control value

is however not included. Therefore, it is necessary to

derive relationship between this rule and interceptor

acceleration command

We assume that closed-loop lateral acceleration

of both interceptor and target can be represented by

equivalent first-order transfer function, by ignoring

model error we have





Ic I I

aaa







(11)





TTcTT

aaa







(12)

where

are the guidance commands of target

and interceptor,



and



are their time constants.

Notably, the acceleration command is restricted to

max

aM

(13)

4.2 Sliding Surface Design

In contrast to the existing methods of HP intercept

guidance law, this paper uses the terminal sliding

mode surface which can converge in a finite time.

We define the HP interception deviation as

The Design of Finite-time Convergence Guidance Law for Head Pursuit based on Adaptive Sliding Mode Control

113









  

(14)

where

n is the time constant. Since interceptor and

target have first order characteristics, the derivation

e is required to have the accelerate command

Lemma 1. (Yu, 2005) For any real numbers



 ,





01k

, an extended Lyapunov condition of

finite-time stability can be given in the form of TSM

  

Vx Vx V x



 



(15)

where the settling time can be estimated by



102













(16)

Define the terminal sliding variable as



eesigne









(17)

where



 ,





. Substituting Eqs (1), (2),

(3), and (14), we can write the sliding variable as



 

snnPsignP

nn PsignP

VV r





   



   

  



(18)

where

Pe



, and differentiating the Eq. (18) as



 

cos cos

Ic I Tc T

II TT

rIT

aa aa

snn

VV r

Vaa

nqe nnq

rVV

















 





   













(19)

Substituting Eqs.(1), (2) and (3), into Eq.(19) as

ITT IcIcTcTc

Ga Ga Gq G a G a



 



(20)

where



 

1cos

cos

21 1

Gn eV

GnneV

Gn n e

























   



 



   















(21)

Therefore, the first-order dynamic characteristic

of sliding variable can be simplified to

I T T q Ic Ic Tc Tc

Ga Ga Gq G a G a 



(22)

4.3 Guidance Law Design

Based on the terminal sliding variable given in

Eq.(17), the sliding mode controller

can be

composed of two parts:

and

To be specific,

is called the equivalent part,

which indicates that if there is no model error and

target maneuvering, the system could continue to

approach within the sliding surface. Meanwhile,

is called the uncertainty part, which means that if the

system has modelling errors and target maneuvering,

this part can drive the system to the designed sliding

surface

, so that the robustness of the system can be

achieved. Therefore,

can be written as

cequc

aaa





(23)









eq I I T T Ic

at Ga Ga GqG



  



(24)

In this paper, we design the uncertainty part of

based on the reaching law as



12k

ks k sig s



 



(25)

where

0k 

, 01





 . According to Eq.

(22) and Eq.(25), it can be written as







ˆˆ

ks ksig s f s























(26)

where

are the estimated gain values. For the

research objective in this paper, it is better to

eliminate the influence of external disturbance and

accelerate the convergence speed of the sliding

surface, thus the adaptive law can be designed as























(27)



























(28)

where





are positive design parameters.

4.4 Stability Proof

Proof. We select the Lyapunov function as

111

22 2

Vss k k





 

(29)

By using the time derivative of the Lyapunov

function, we have

ICINCO 2016 - 13th International Conference on Informatics in Control, Automation and Robotics

114











11 2 2

12 11

22 max

12 max

ˆˆ

Tc Tc

Tc T

Vs ksksigsGa

kks kks

ks k s k k s

kks Ga s

ks k s Ga s









 

 

   

 

  



(30)

In order to make

0V 



, Eq.(30) can be rewritten

into the following two forms as

max

-2 - 2

Tc T

Vk V kV















(31)

max

Tc T

VV k V











  







(32)

If we want to make





, the initial values of

parameters

and

should meet the following

conditions as

max

Tc T



(33)

max

Tc T





(34)

Consequently, both Eq.(31) and Eq.(32) can be

simplified as

0VVV







 



(35)

where





2 k









According to the Lemma 1, we can figure out

that the sliding surface defined in Eq.(17) will be

driven onto the plane of

0s 

in finite time, which

can be mathematically described as

10 2



























(36)

From Eq.(14) and Eq.(17), it can be seen that the

plane

0s 

is not qualified to meet the condition of

head pursuit intercept, which is

0e 

. Therefore, we

prove that the system can reach the origin from the

sliding surface.

When

0s 

, if

0e 



, then



0esigne







As a result,

0e 

and the parameter e will increase

along with the increase of time, and finally tends to

zero. If

0e 



, then



0esigne







, so

0e 

, and

e will decreases until finally tends to 0 too. This

shows that the states of the system will convergence

to the origin in finite time.

5 SIMULATION EXPERIMENT

AND ANALYSIS

In this section, we apply the proposed approach in

experimental scenario by using numerical simulation

to validate the effectiveness.

Table 1: Simulation parameters setup.

Interceptor Target Guidance

= 1600m/s V

= 2000m/s n = 2

= 0.2s

Notably, the targets with constant velocity and

constant maneuvering (20g,-20g) are considered to

test the designed method. Moreover, we analyze the

change of interceptor trajectory, overload and sliding

surface in multiple attack angles. The simulation

parameters are given in Table 1.

According to Table 1, when the initial LOS angle

q is 20 deg, the initial distance between the target

and interceptor is

(0)r =3000m, [20,0,20]g

a 

and





. 3 scenarios are tested: non-maneuvering

target and two constant maneuvering targets. In

Figure 3, the trajectories of both interceptor and

target are graphically demonstrated.

0 2000 4000 6000 8000 10000 12000 14000

-6000

-4000

-2000

2000

4000

6000

8000

X( m )

Y(m)

target

interceptor

aT=20g

aT=0g

aT=-20g

Figure 3: Response curves of intercept trajectory.

-25 -20 -15 -10 -5 0 5 10

500

1000

1500

2000

2500

3000



(deg)

r(m)

aT=20g

aT=0g

aT=-20g

Figure 4: Response curves of trjectories in target

coordinate system;

0deg





The Design of Finite-time Convergence Guidance Law for Head Pursuit based on Adaptive Sliding Mode Control

115

From Figure 3 we can see that, whether if the

target has maneuvering or not, the trajectory of

interceptor will gradually approach to the trajectory

of target and track it until it is caught up. In Figure 4

and 5, the relative trajectories of interceptor in non-

rotating polar coordinate attached to the target are

given. It can be seen from the figure that, the

interception is successfully achieved in the presence

of target maneuvers and the initial heading errors

(

(0) 20deg



 ), while the angle error is small. To

be specific, as we set





in Figure 4, the angle

errors are 0.34deg and 0.05deg while the

of target

maneuvering are 20g and -20g, respectively. In

Figure 5,



is set to be -10deg.

-30 -25 -20 -15 -10 -5

500

1000

1500

2000

2500

3000



(deg)

r(m )

aT=20g

aT=0g

aT=-20g

Figure 5: Response curves of trjectories in target

coordinate system;

10deg



 .

From the experimental results we can see that,

the angle errors are 0.12deg and 0.29deg separately,

while the corresponding

a of target maneuvering

are 20g and -20g. Moreover, both Figure 4 and 5

show that the angle error is almost zero if the target

has no maneuver.

0 1 2 3 4 5 6 7 8

-100

-80

-60

-40

-20

t(s)

aI(g)

aT=0g

aT=20g

aT=-20g

Figure 6: Response curves of interceptor acceleration;

0deg



 .

0 1 2 3 4 5 6 7 8

-80

-60

-40

-20

(

)

aI(g)

aT=20g

aT=0g

aT=-20g

Figure 7: Response curves of interceptor acceleration

10deg



 .

Considering that both target and interceptor are

set to be the typical high-speed target, the results

show a good performance. As shown in Figure 6 and

7, the response curves of interceptor acceleration for

different target maneuvers are presented respectively,

where





and

10deg





0 0.5 1 1.5 2 2.5 3 3.5 4

-2

-1

t(s)

s(deg)

aT=20g

aT=0g

aT=-20g

Figure 8: Response curves of sliding surface

value; 0deg





0 0.5 1 1.5 2 2.5 3 3.5 4

-4

-2

t(s)

s(deg)

aT=20g

aT=0g

aT=-20g

Figure 9: Response curves of sliding surface

value; 10deg





 .

We can see that the magnitude of the interceptor

acceleration is adjusted dynamically over time. The

change of interceptor acceleration decreases after a

short period of time. Finally, the tracking of target is

realized. Compared with the head pursuit guidance

laws that proposed in recent years, the maneuvering

acceleration of interceptor is greatly reduced.

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The value of the sliding variable for





and

10deg



 are graphically showed in Figure 8 and

9, respectively. Obviously, it also can be seen from

Figure 8 and 9 that, the sliding variable

could

convergence to the sliding surface rapidly, then

reach steady state.

In order to further illustrate the effectiveness and

the advance of the guidance law, we compared it

wih the guidance law proposed in paper (Dan, 2013).

Table 2 shows the intercept time under different

target maneuvers.

Moreover, in order to evaluate the convergence

rate of the proposed method, the comparison of

interception time between our method and the

guidance law proposed in (Dan, 2013) are presented.

The comparison results are given in the Table 2, in

which 4 target acceleration values are applied.

Table 2: Intercept time of the two guidance law.

10g 15g 20g 25g

Our

8.413s 7.982s 7.523s 7.051 s

Dan 13.827s 13.304s 12.506s 11.563s

We can see that the guidance law proposed in

this paper has shorter intercept time and has better

convergence performance.

6 CONCLUSIONS

In this paper, a finite time convergent guidance law

for head pursuit is proposed, in which the terminal

sliding mode control theory is used. By considering

the dynamics characteristics of target and interceptor,

an adaptive law is theoretically designed based on

the interference factors of target maneuvering and

model errors. The results of numerical simulation

show that the guidance law can be implemented on

the head pursuit intercept of high-speed targets and

achieve successful interception in different attack

angles and target maneuvering, while having smaller

intercept error compared with other methods. The

proposed method has lower requirement on the way

of maneuvering, which show a potential application

in real interception of high-speed vehicle. Moreover,

the sliding variable can also convergence to sliding

surface more quickly with strong robustness.

ACKNOWLEDGEMENTS

This work was supported by the National Natural

Science Foundation of China under Grant 61502391,

the Foundation of National Key Laboratory of

Aerospace Flight Dynamics and the China Space

Foundation under Grant 2015KC020121.

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