Ch18-I044963.fm  Page 85  Tuesday, August 1, 2006  2:59 PM
                           Tuesday, August
                      Page 85
                                     1, 2006
            Ch18-I044963.fm
                                          2:59 PM
                                                                                          85 85






                      -3  - 2 - 1 0  1                                -3  -2  - 1
                            (a)  0.00 s             (b)  1.00 s             (c)  2.00 s











                            (d)  3.00 s             (e)  4.00 s             (f)  5.00 s
                            Figure  4:  Process  of indirect  simultaneous  positioning  to  desired  points

                  three  points P3, P,i, and  P H . Positioned  displacements  are  u-,.. T , u- h!J, ug, x, ue_ y, «io, 3-, and  u\a. y  and
                  manipulated  displacements  are  u^, x,  u$, y,  'Ui.. T , u^ y,  an,,,  and  uii iV,  as illustrated  in  Figure  2-(a).
                  Let  us introduce  a distance-based  mapping  from  the  positioned  displacements  to the  manipulated
                  displacements.  Control  law  is then  formulated  as  follows:
                      u ?l  =  -K[  J o * (u 6  -  u* 6) dt,  Ui  =  -Ki  /„* (u 5  -  Ug)  dt,  u 14  =  -Kj  /„* (u 10  -  u| 0 )  dt.
                  The  corresponding  discrete  control  law  is given  by



                              K
                                                                              K
                    4 J  1  =  "3,!, - 'l(4,y  -  «6,s,)-  "ta  1  =  «4,j, ~  *"/(«*», ~  «5,!/),  «14^ =  "14,9 ~ l(4o,y  ~  «10,j,)-
                  Elastic  and  viscous  moduli  are  A da  =  7.0,  A vis  =  4.0,  /i' :la  =  5.0,  and  /i vis  =  2.0.  Density
                  is  given  by  p  =  0.2.  Positioned  displacements  are  measured  at  time  interval  T  =  0.5.  Let
                                                                       T
                                                                                       T
                  desired  values  of  the  positioned  displacements  be  u% =  [-0.20,0.10] ,  Ug  =  [0.30. -0.10] ,  and
                               T
                  w* 0 — [0.10, 0.30] .  Motion  of the positioned  displacements  is plotted  in Figure 3.  Gain is given by
                  Ki  — 1.7.  Vibration conies from the viscoclastic nature  of the object.  Despite  of the vibration,  the
                  positioned  displacements  converge to their  desired values, as shown  in the figure.  Deformed  shapes
                  during the  positioning  process  are  described  in Figure  4.  Crosses  in the  figures  denote  the  desired
                  values  of  the  positioned  displacements.  As  shown  in  the  figure,  the  positioned  displacements
                  converge  to their  desired  values.
                     Let  us  guide the  x-coordinates  of P5, Pg,  and  P10 to  their  desired  values  by  controlling the  x-
                                                                 ^
                  coordinates  of P3, P4, and  P14.  Positioned  displacements  are j . ,  11^.,.,  and  «io,.x- and  manipulated
                  displacements  are  u$, x,  ?/ 4ia:,  and  a^,,  as  illustrated  in  Figure  2-(b).  The  discrete  control  law  is
                  then  given  by
                  Let  desired values  of the positioned  displacements  be u\ x  — 0.20,  u* ix  =  —0.20, and  u\ Ox  — —0.20.
                  Deformed  shapes  during  the  positioning  process  are  described  in  Figure  5.  Dotted  lines  in  the
                  figures  denote  the  desired  values  of  the  positioned  displacements.  As  shown  in  the  figure,  the
                  positioned  displacements  converge  to  their  desired  values.