source: Sophya/trunk/Poubelle/archTOI.old/arcunit.h@ 1000

#define ARCUNIT_H


/*======================================================================*/
/*                                                                      */
/*               arcunit.h  :   conversion en mesure physique                   */
/*                                                                      */
/*======================================================================*/



/* ----------------------------   prototypes des fonctions       ------------------------------ */
/* -------------------------------------------------------------------------------------------- */


double          bolo_muV        (param_bolo*    param_pt,       reglage_bolo*   reglage_pt, int valbrut,int indice_bolo);                                                                                       
double          bolo_temp       (param_bolo*    param_pt,       reglage_bolo*   reglage_pt, double R,int indice_bolo);

double          DAC_muV         (param_bolo*    param_pt,       reglage_bolo*   reglage_pt, int indice_bolo);
double          DAC_muA         (param_bolo*    param_pt,       reglage_bolo*   reglage_pt, int indice_bolo);

int     voyant_EVO(block_type_dilution* blk);
int     voyant_EVF(block_type_dilution* blk);
int     commande_EVO(block_type_dilution*       blk);
int     commande_EVF(block_type_dilution*       blk);
int     commande_EVB(block_type_dilution*       blk);
int     commande_EVV(block_type_dilution*       blk);


double pression_entree_3He(block_type_dilution* blk);   
double debit_3He(block_type_dilution*   blk)    ;
double pression_sortie_3He(block_type_dilution* blk)    ;
double pression_entree_4He(block_type_dilution* blk)    ;
double debit_4He(block_type_dilution*   blk)    ;
double pression_sortie_4He(block_type_dilution* blk)    ;
double pression_air_vanne(block_type_dilution*  blk)    ;
double pression_pompe_charbon(block_type_dilution*      blk);   
double pression_membranne(block_type_dilution*  blk)    ;
double pression_externe(block_type_dilution*    blk)    ;
double tension_pile_10T(block_type_dilution*    blk)    ;
double tension_pile_p18D(block_type_dilution*   blk)    ;
double tension_pile_m18D(block_type_dilution*   blk)    ;
double tension_pile_10B(block_type_dilution*    blk)    ;
double tension_pile_p18B(block_type_dilution*   blk)    ;
double tension_pile_m18B(block_type_dilution*   blk)    ;
double tension_pile_Ch(block_type_dilution*     blk)    ;
int switch_pile_5(block_type_dilution*  blk)    ;
int switch_pile_15(block_type_dilution* blk)    ;
double  temperature_caisson_haut1(block_type_dilution*  blk)    ;
double  temperature_caisson_haut2(block_type_dilution*  blk)    ;
double  temperature_caisson_bas1(block_type_dilution*   blk)    ;
double  temperature_caisson_bas2(block_type_dilution*   blk)    ;
double  temperature_caisson_tube_helium(block_type_dilution*    blk)    ;
double  temperature_caisson_piles(block_type_dilution*  blk)    ;
double  temperature_caisson_driver_moteur(block_type_dilution*  blk)    ;
double  pression_helium_bain(block_type_dilution*       blk)    ;
double  pression_pirani(block_type_dilution*    blk)    ;




/*      cette fonction transforme un char (sur 8 bit) en double avec une echelle logarythmique  */
/*      elle est en particulier utilisée pour calculer les coef de la regul                     */

double          val_double(char x);

/*      cette fonction transforme un char (sur 8 bit) en entier int4 (echelle logarythmique)    */
/*      elle est en particulier utilisée pour fixer le courant sur les bolometres               */

unsigned        int4    val_long(char x);

int                     new_val_dac(int a,char  code); 



/* ----------------------------   define utilise pour les calculs        ------------------------------ */


#define bol_micro_volt(val,gain)        ((1e7*(double)val)/(65536.*gain))
/*  avec  gain = (double)parametr.bolo[bolo].bolo_gain*gain_ampli(reglage.bolo[bolo])                           */
                

/* gains 0 .. 15 pour MLPA  ///   gain 16..19  pour BEBO   ///   gain 20..22  pour BEDIF        */              
#define def_gains       double gains_reels[32]={1,2,4,8,10,20,40,80,100,200,400,800,1000,2000,4000,8000,0.5,2.5,10,50,0.93,3.777,18.974};
                /*                      gain bediff    10->9.3    40->37.77     200->189.74             */

#define         gain_ampli(aa)  gains_reels[gainbrut(aa)]               



#define bit_piles_5V    1
#define bit_piles_15V   2
#define bit_piles_auto  4


/*      signification des bit lus dans switch_dil       */
#define switch_EVF              0x00000080      /*      contact fin de course vanne fermee      */
#define switch_EVO              0x00000040      /*      contact fin de course vanne ouverte     */

/* les bit suivants sont envoyés par telecommande et relus dans switch_dil      */
#define switch_helium           0x00200000      /*  13: commande sond niveau helium     */
#define switch_pile_par_5       0x00100000      /*  12: mise en parallele des piles pour le 5V  */
#define switch_pile_par_15      0x00080000      /*  11: mise en parallele des piles pour le 15V */
#define vanne_EVB               0x00008000      /*  7: commande vanne brooks    */
#define vanne_EVO               0x00010000      /*  8: commande vanne EVO       */
#define vanne_EVV               0x00020000      /*  9: commande vanne EVV       */
#define vanne_EVF               0x00040000      /*  10: commande vanne EVF      */
#define chauffage1              0x00004000      /*  6: chauffage 1      */
#define chauffage2              0x00002000      /*  5: chauffage 1      */
#define chauffage3              0x00001000      /*  4: chauffage 1      */
#define chauffage4              0x00000800      /*  3: chauffage 1      */
#define chauffage5              0x00000400      /*  2: chauffage 1      */
#define chauffage6              0x00000200      /*  1: chauffage 1      */
#define chauffage7              0x00000100      /*  0: chauffage 7      */

#ifndef ARCUNIT_H
enum{nbit_chauffage7,nbit_chauffage6,nbit_chauffage5,nbit_chauffage4,nbit_chauffage3
        ,nbit_chauffage2,nbit_chauffage1,nbit_vanne_EVB,nbit_vanne_EVO
        ,nbit_vanne_EVV,nbit_vanne_EVF,nbit_switch_pile_par_15,nbit_switch_pile_par_5,nbit_switch_helium};

/*  position des mesures sur les multiplexeurs          */
/* J10A  ->  temperatures basses t_b1 t_b2,t_b3 t_b4 36 37 41 35        */ 
/* J10B  ->  temperatures basses t_a1 t_a2,t_a3 t_a4 38 11 34 28        */ 
/* J1??  ->  temperatures hautes t_h1 t_h2,t_h3 t_h4    */ 

enum{
/* multiplex11..18:*/   t_a2    ,mul12_ ,p_haut ,p_memb ,t_h1   ,t_h4   ,t_h3   ,t_h2   
/* multiplex21..28:*/,  mul21_  ,mul22  ,p_charb,p_R4   ,mul25_ ,p_C3   ,p_R3   ,t_a4   
/* multiplex31..38:*/,  mul31_  ,p_C4   ,p_air  ,t_a3   ,t_b4   ,t_b1   ,t_b2   ,t_a1   
/* multiplex41..48:*/,  t_b3    ,d_4He  ,RP_He  ,t_pile ,d_3He  ,j_he3  ,j_he7  ,j_he4  
/* multiplex51..58:*/,  j_he5   ,j_he1  ,j_he8  ,j_he2  ,j_he6  ,pirani ,mul57  ,mul58  
/* multiplex61..68:*/,  p_m18B  ,p_10B  ,p_m18D ,mul64  ,p_p18B ,p_10T  ,p_Ch   ,p_p18D         
        };
/* reste libres :  mul   12 - 21 - 22 - 25 -  31 - 44 - 57 - 58 - 64    */
/* T_A1 EST AUSSI LE DRIVER DU MOTEUR DE PIVOT   */

#endif

#define  val_multiplex(qq)      (0.0003052*(double)((qq)-0x8000))       
#define  val_temperature(qq)    ((val_multiplex(qq)<0.2)?-99:((1146.3/(val_multiplex(qq)-0.1)) - 245.13))