ÄÜÅÙÃ÷ »ó¼¼º¸±â
MPC(Model Predictive Control) ¸ðÅÚÀ» ÅëÇÑ °æ·Î ÃßÀû Á¦¾î ºÐ¼®¿¬±¸


MPC(Model Predictive Control) ¸ðÅÚÀ» ÅëÇÑ °æ·Î ÃßÀû Á¦¾î ºÐ¼®¿¬±¸

MPC(Model Predictive Control) ¸ðÅÚÀ» ÅëÇÑ °æ·Î ÃßÀû Á¦¾î ºÐ¼®¿¬±¸

,< Hyuk-Jun Chang> Àú | ¾ÆÁø

Ãâ°£ÀÏ
2020-07-10
ÆÄÀÏÆ÷¸Ë
ePub
¿ë·®
13 M
Áö¿ø±â±â
PC½º¸¶Æ®ÆùÅÂºí¸´PC
ÇöȲ
½Åû °Ç¼ö : 0 °Ç
°£·« ½Åû ¸Þ¼¼Áö
ÄÜÅÙÃ÷ ¼Ò°³
¸ñÂ÷
ÇÑÁÙ¼­Æò

ÄÜÅÙÃ÷ ¼Ò°³

In this paper, explicit Model Predictive Control(MPC) is employed for automated
lane-keeping systems. MPC has been regarded as the key to handle such
constrained systems. However, the massive computational complexity of MPC,
which employs online optimization, has been a major drawback that limits the
range of its target application to relatively small and/or slow problems. Explicit
MPC can reduce this computational burden using a multiparametric quadratic
programming technique(mp-QP). The control objective is to derive an optimal front
steering wheel angle at each sampling time so that autonomous vehicles travel
along desired paths, including straight, circular, and clothoid parts, at high entry
speeds. In terms of the design of the proposed controller, a method of choosing
weighting matrices in an optimization problem and the range of horizons for
path-following control are described through simulations. For the verification of
the proposed controller, simulation results obtained using other control methods
such as MPC, Linear-Quadratic Regulator(LQR), and driver model are employed,
and CarSim, which reflects the features of a vehicle more realistically than
MATLAB/Simulink, is used for reliable demonstration.

¸ñÂ÷

Á¦ 1Æí : SIMULINK ±âº»Æí

1.1 SIMULINKÀÇ ½ÃÀÛ 1
ºí·ÏÀÇ ¿¬°á 5
ºí·Ï ÆĶó¹ÌÅÍÀÇ ¼³Á¤ 7
½Ã¹Ä·¹ÀÌ¼Ç ÆĶó¹ÌÅÍ (Configuration Parameters)ÀÇ ¼³Á¤ 8
½Ã¹Ä·¹À̼ÇÀÇ ¼öÇà 9
ºí·Ï ÆĶó¹ÌÅÍÀÇ Ç¥½Ã 9
º¹¼ö µ¥ÀÌÅÍÀÇ Ç¥½Ã 11
2.2 µ¿Àû ½Ã¹Ä·¹ÀÌ¼Ç 13
ÀÌÂ÷ ¹ÌºÐ¹æÁ¤½Ä 17
¼±Çü »óź¯¼ö ¸ðµ¨ 23
DC ¸ðÅÍÀÇ ½Ã¹Ä·¹ÀÌ¼Ç 24
ÇÔ¼ö ºí·ÏÀÇ »ç¿ë 29
Â÷ºÐ¹æÁ¤½Ä(difference equation)ÀÇ ¸ðµ¨¸µ 34
Subsystem(ºÎ½Ã½ºÅÛ)ÀÇ ±¸¼º 37

Á¦ 2Æí : ¿¬±¸³í¹®
Analysis of explicit model predictive control for path-following control

1. Introduction 41
2. Vehicle model 44
3. Explicit model predictive control 45
4. Controller design 49
5. Explicit MPC controller design 50
6. Results 53
7. Conclusions 56
8. References 58