Lib herkulex utilisée pour la carte du phare
fonctions_herkulex.cpp
- Committer:
- thesnowfoxy
- Date:
- 2021-07-12
- Revision:
- 19:aaa97ea138fd
- Parent:
- 18:41bce61db461
File content as of revision 19:aaa97ea138fd:
#include "mbed.h" #include "fonctions_herkulex.h" //#include "ident_crac.h" Timer Time_out; //-------------------------Définition des ports série--------------------------- //RawSerial pc(USBTX, USBRX,115200); RawSerial serial1(PB_6,PB_7,115200); // P : 41 et 42 RawSerial serial2(PA_2,PA_3,115200); // P : 43 et 47 RawSerial serial3(PA_2,PA_3,115200); // P : 44 et 48 RawSerial serial4(PA_2,PA_3,115200); // P : 45 RawSerial serial5(PA_2,PA_3,115200); // P : 46 //----------------------------variables de reception---------------------------- uint8_t rx[300]; uint8_t rx2[256]; unsigned char size_reponse=100; unsigned char recevoir = 0; unsigned char i2 = 0; unsigned char flag_serial1_receive2 = 0; //--------------------variables et fonction de verification--------------------- #define tolerance_en_position 16 //1 degre=(1002-21)/320=3.066position #define tolerance_en_position_negatif -16 #define B_tolerance_en_position 16 //1 degre=(1002-21)/320=3.066position #define B_tolerance_en_position_negatif -16 #define V_b 45 //temps d'attente de bras #define V_m 45 //temps d'attente de bras #define V_h 45 //temps d'attente de bras #define TEMPO_R 16 //temps d'attente de reception #define PWM_recl 0.6 #define temps_servo_G 65 //temps d'attente des servos sauf 2 bras #define new_tempoX 45 //temps d'attente de correction double int16_t pos_position = 0, get_pos = 0, pos_ID = 0; uint8_t pos_led = 0, Status = 0,iID = 0; uint8_t nombre_servo = 0; uint8_t pos_time = 0; uint16_t position_servo_mul[20]; uint8_t data_servo_mul[40]; uint8_t flag_correction = 0; float new_tempo=0; float tab_tempo[20]; uint16_t position_servo_mul_different[20]; uint8_t data_servo_mul_different[60]; int8_t my_Tor = 0; int8_t Tension_inter = 0; double Tension = 0; uint8_t coeffient_time = 1; uint8_t veri = 0; typedef enum {pos,vitesse,pos_mul_complex,pos_mul_complex_different} type_etat ; unsigned char serial_numero = 0; static type_etat etat=pos; int nb_erreur_pas_de_couple = 0; int nb_erreur_pos = 0; //---------------------fonction d'interruption de reception de serial1--------------------- /* *Ici on crée une interruption afin de rendre prioritaire la réception de données *!!! Pour utiliser les fonctions utilisant les interruptions, il faut 'activer' ces dernières *!!!avec la fonction servo_interrupt_en(); */ unsigned char flag_perdu_info_serial1 = 0, indicateur_serial1 = 0, Size_trame_serial1 = 0, old_valueserial1 = 0; unsigned char char_receive_pc[100]; unsigned char char_receive_serial1[100]; unsigned char valueserial1=0; unsigned char valuepc=0,flag_seconde=0,flag_pc_receive=0,flag_serial1_receive=0; int pospos; // //La fonction receive_serial1() est appelée par la fonction d'interruption //elle appelle la fonction automate_serial() et range les données reçues dans un tableau // void receive_serial1() { char_receive_serial1[valueserial1]=serial1.getc(); automate_serial1(); } // //fonction d'interruption // elle se déclenche dès que des données se trouvent sur le port de réception // elle appelle alors immédiatement la fonction receive_serial1(); // void Interrupt1_en(void) { serial1.attach(&receive_serial1,Serial::RxIrq); } bool verification() { uint8_t i = 0; switch(etat) { case pos: //------------------------Status-------------------- Status = getStatus(pos_ID,serial_numero); wait_ms(3); ////pc.printf("status = %d",Status); switch(Status) { case 0: break; case 2: //Exceed allowed POT limit //pc.printf("ERR-Depasse la limite de position\n"); //clean_ERR(pos_ID); //wait_ms(500); clear(pos_ID,serial_numero); //positionControl(pos_ID, 1000, 3, GLED_ON); wait_ms(3); Status = getStatus(pos_ID,serial_numero); wait_ms(3); ////pc.printf("status = %d",Status); break; } //------------------Torque et position------------------------------ my_Tor = Get_Torque(pos_ID,serial_numero); wait_ms(5); ////pc.printf("my_Tor = %x\n",my_Tor); while(my_Tor != 0x60) { setTorque(pos_ID,TORQUE_ON,serial_numero); my_Tor = Get_Torque(pos_ID,serial_numero); wait_ms(5); } Tension_inter = Get_Tension_actuelle(pos_ID,serial_numero); Tension = Tension_inter*0.074; if(Tension <=6.60) { coeffient_time = 6; } else if(Tension <= 6.90) { coeffient_time = 4; } else if(Tension <= 7.10) { coeffient_time = 2; } else if(Tension > 7.10) { coeffient_time = 1; } get_pos = getPos(pos_ID,serial_numero); //pc.printf("P4=%d ",get_pos); if(((get_pos - pos_position)>tolerance_en_position)||((get_pos - pos_position)<tolerance_en_position_negatif)) { if((get_pos - pos_position)>tolerance_en_position) { new_tempo=(get_pos - pos_position)*0.084*coeffient_time + 1; if (new_tempo > 254) new_tempo = 254; } else if((get_pos - pos_position)<tolerance_en_position_negatif) { new_tempo=(get_pos - pos_position)*0.084*coeffient_time +1; if (new_tempo > 254) new_tempo = 254; } positionControl(pos_ID, pos_position, new_tempo, pos_led,serial_numero); //pc.printf("Correction!\n"); } break; case pos_mul_complex: //---------------------------Status--------------------------- for(i=0; i<nombre_servo; i++) { Status = getStatus(data_servo_mul[1+2*i],serial_numero); //pc.printf("status = %d",Status); switch(Status) { case 0: break; case 2: //Exceed allowed POT limit ////pc.printf("ERR-Depasse la limite de position\n"); //clean_ERR(id); //wait_ms(500); clear(data_servo_mul[1+2*i],serial_numero); //positionControl(id, 1000, 3, GLED_ON); //wait_ms(3); //Status = getStatus(data_servo_mul[1+2*i]); //wait_ms(3); ////pc.printf("status = %d",Status); break; } } //----------------------Torque et position-------------------------- for(i=0; i<nombre_servo; i++) { my_Tor = Get_Torque(data_servo_mul[1+2*i],serial_numero); //Time_out.reset(); //Time_out.start(); while((my_Tor != 0x60))//&&(Time_out.read_ms()<100) ) { setTorque(data_servo_mul[1+2*i],TORQUE_ON,serial_numero); my_Tor = Get_Torque(data_servo_mul[1+2*i],serial_numero); ////pc.printf(" SET_TORQUE "); Status = getStatus(data_servo_mul[1+2*i],serial_numero); clear(data_servo_mul[1+2*i],serial_numero); Status = getStatus(data_servo_mul[1+2*i],serial_numero); } //Time_out.stop(); } veri = 0; //Time_out.reset(); //Time_out.start(); while((veri < nombre_servo))//&&(Time_out.read_ms()<100)) { for(i=0; i<nombre_servo; i++) { my_Tor = Get_Torque(data_servo_mul[1+2*i],serial_numero); //Time_out.reset(); //Time_out.start(); while((my_Tor != 0x60))//&&(Time_out.read_ms()<100)) { setTorque(data_servo_mul[1+2*i],TORQUE_ON,serial_numero); my_Tor = Get_Torque(data_servo_mul[1+2*i],serial_numero); ////pc.printf(" SET_TORQUE "); Status = getStatus(data_servo_mul[1+2*i],serial_numero); clear(data_servo_mul[1+2*i],serial_numero); Status = getStatus(data_servo_mul[1+2*i],serial_numero); } //Time_out.stop(); } for(i=0; i<nombre_servo; i++) { Tension_inter = Get_Tension_actuelle(data_servo_mul[1+2*i],serial_numero); Tension = Tension_inter*0.074; if(Tension <=6.60) { coeffient_time = 6; } else if(Tension <= 6.90) { coeffient_time = 4; } else if(Tension <= 7.10) { coeffient_time = 2; } else if(Tension > 7.10) { coeffient_time = 1; } get_pos = getPos(data_servo_mul[1+2*i],serial_numero); //pc.printf("PosiM=%d ",get_pos); if((get_pos - position_servo_mul[i])>tolerance_en_position) { tab_tempo[i]=(get_pos - position_servo_mul[i])*0.084*coeffient_time+1; //MinTempo pour 1 position:((320/60)*0.17)/(1000-20)=0.94ms MinPlayTime pour 1 position:0.94ms/11.2ms=0.084 if (tab_tempo[i] > 254) tab_tempo[i] = 254; flag_correction = 1; } else if((get_pos - position_servo_mul[i])<tolerance_en_position_negatif) { tab_tempo[i]=(position_servo_mul[i] - get_pos)*0.084*coeffient_time+1; if (tab_tempo[i] > 254) tab_tempo[i] = 254; flag_correction = 1; } } if(flag_correction == 1) { new_tempo = 0; for(i=0; i<nombre_servo; i++) { if(tab_tempo[i]>new_tempo) { new_tempo = tab_tempo[i]; } } flag_correction = 0; positionControl_Mul_ensemble_complex(nombre_servo,new_tempo,data_servo_mul, position_servo_mul,serial_numero); //pc.printf("Correction!\n"); } veri=0; for(i=0; i<nombre_servo; i++) { get_pos = getPos(data_servo_mul[1+2*i],serial_numero); //pc.printf("PosiM=%d ",get_pos); if((get_pos - position_servo_mul[i])>tolerance_en_position) { tab_tempo[i]=(get_pos - position_servo_mul[i])*0.084*coeffient_time+1; //MinTempo pour 1 position:((320/60)*0.17)/(1000-20)=0.94ms MinPlayTime pour 1 position:0.94ms/11.2ms=0.084 if (tab_tempo[i] > 254) tab_tempo[i] = 254; flag_correction = 1; } else if((get_pos - position_servo_mul[i])<tolerance_en_position_negatif) { tab_tempo[i]=(position_servo_mul[i] - get_pos)*0.084*coeffient_time+1; if (tab_tempo[i] > 254) tab_tempo[i] = 254; flag_correction = 1; } else { //if(((get_pos - position_servo_mul[i])<tolerance_en_position)&&((get_pos - position_servo_mul[i])>tolerance_en_position_negatif)) veri++; } } } //Time_out.stop(); break; case pos_mul_complex_different: //---------------------------Status--------------------------- for(i=0; i<nombre_servo; i++) { Status = getStatus(data_servo_mul_different[1+3*i],serial_numero); ////pc.printf("status = %d",Status); switch(Status) { case 0: break; case 2: //Exceed allowed POT limit ////pc.printf("ERR-Depasse la limite de position\n"); //clean_ERR(id); //wait_ms(500); clear(data_servo_mul_different[1+3*i],serial_numero); //positionControl(id, 1000, 3, GLED_ON); //wait_ms(3); //Status = getStatus(data_servo_mul_different[1+2*i]); //wait_ms(3); ////pc.printf("status = %d",Status); break; } } //-------------------Torque et position----------------------------- for(i=0; i<nombre_servo; i++) { my_Tor = Get_Torque(data_servo_mul_different[1+3*i],serial_numero); while(my_Tor != 0x60) { setTorque(data_servo_mul_different[1+3*i],TORQUE_ON,serial_numero); my_Tor = Get_Torque(data_servo_mul_different[1+3*i],serial_numero); //wait_ms(5); ////pc.printf(" SET_TORQUE "); } } for(i=0; i<nombre_servo; i++) { Tension_inter = Get_Tension_actuelle(data_servo_mul_different[1+3*i],serial_numero); Tension = Tension_inter*0.074; if(Tension <=6.60) { coeffient_time = 6; } else if(Tension <= 6.90) { coeffient_time = 4; } else if(Tension <= 7.10) { coeffient_time = 2; } else if(Tension > 7.10) { coeffient_time = 1; } get_pos = getPos(data_servo_mul_different[1+3*i],serial_numero); //pc.printf("PosiM=%d ",get_pos); if((get_pos - position_servo_mul_different[i])>tolerance_en_position) { tab_tempo[i]=(get_pos - position_servo_mul_different[i])*0.084*coeffient_time+1; //MinTempo pour 1 position:((320/60)*0.17)/(1000-20)=0.94ms MinPlayTime pour 1 position:0.94ms/11.2ms=0.084 if (tab_tempo[i] > 254) tab_tempo[i] = 254; data_servo_mul_different[2+3*i] = tab_tempo[i]; flag_correction = 1; } else if((get_pos - position_servo_mul_different[i])<tolerance_en_position_negatif) { tab_tempo[i]=(position_servo_mul_different[i] - get_pos)*0.084*coeffient_time+1; if (tab_tempo[i] > 254) tab_tempo[i] = 254; data_servo_mul_different[2+3*i] = tab_tempo[i]; flag_correction = 1; } } if(flag_correction == 1) { flag_correction = 0; positionControl_Mul_ensemble_different_complex(nombre_servo,data_servo_mul_different, position_servo_mul_different,serial_numero); //pc.printf("Correction!\n"); } break; } return true; } // //La fonction verification_3_bras() sert à vérifier les bras utilisés après un mouvement groupé //Elle change les numéros de sérial et des cerveaux moteurs // void verification_3_bras(uint8_t sens_avant) { uint8_t i=0, idata=0; uint8_t servos_bras_avant[6] = {RLED_ON, 1, GLED_ON, 2, BLED_ON, 3}; uint8_t servos_bras_arriere[6] = {RLED_ON, 4, GLED_ON, 5, BLED_ON, 6}; if(sens_avant==1) { for(idata=0;idata<6;idata++) { data_servo_mul[idata] = servos_bras_avant[idata]; } } else if(sens_avant==0) { for(idata=0;idata<6;idata++) { data_servo_mul[idata] = servos_bras_arriere[idata]; } } for(i=0; i<3; i++) { serial_numero=i+1; verification(); } } // //La fonction automate_serial1() sert à vérifier la bonne réception des données //elle est automatiquement appelée par la fonction receive_serial1() // void automate_serial1() { typedef enum {Attente,FF,Size,Data} type_etat1; static type_etat1 etat1=Attente; ///////pc.printf("coucou"); //////pc.printf("%d\r\n", char_receive_serial1[valueserial1]); switch (etat1) { // état Attente //on attend la réception des données //si on reçois l'octet 0xFF, il s'agit d'un début de trame //on passe à l'état suivant // case Attente: if(char_receive_serial1[0] == 0xFF) { etat1 = FF; valueserial1 = 1; } break; // état FF //on attend le second octet 0xFF pour confirmer qu'il s'agit d'une trame //si on reçoit l'octet 0xFF, il s'agit bien d'une trame Herkulex //on passe à l'état suivant //Sinon on retourne à l'état précédent // case FF: if(char_receive_serial1[1] == 0xFF) { etat1 = Size; valueserial1 = 2; } else { etat1 = Attente; valueserial1 = 0; flag_perdu_info_serial1 = 1; //flag_perdu_info_serial1 } break; // état size //On vérifie si l'octet size est supérieur à la taille minimale d'une trame Herkulex, //Si oui on passe à l'état suivant //Si non on passe à l'état attente et flag_perdu_info_serial1 passe à 1 pour signaler la perte d'information case Size: if(char_receive_serial1[2] < 7) { etat1 = Attente; valueserial1 = 0; flag_perdu_info_serial1 = 1; //flag_perdu_info_serial1 } else { etat1 = Data; old_valueserial1 = 2; valueserial1 = 3; } Size_trame_serial1 = char_receive_serial1[2]; break; //état data //on verifie que la taille de la trame reçue correspond à celle indiquée dans l'octet 'size' //si oui //flag_serial1_receive passe à 1 pour indiquer que la trame à bien été transmise case Data: if((valueserial1-2)==(Size_trame_serial1-3)) { flag_serial1_receive = 1; etat1 = Attente; valueserial1 = 0; } else { valueserial1++; } break; default: break; } } //---------------------fonction d'interruption de reception de serial2--------------------- //même principe que la fonction d'interrutpion de serial1 unsigned char flag_perdu_info_serial2 = 0, indicateur_serial2 = 0, Size_trame_serial2 = 0, old_valueserial2 = 0; unsigned char char_receive_serial2[100]; unsigned char valueserial2=0; unsigned char flag_serial2_receive=0; void receive_serial2() { char_receive_serial2[valueserial2]=serial2.getc(); automate_serial2(); } void Interrupt2_en(void) { serial2.attach(&receive_serial2,Serial::RxIrq); } void automate_serial2() { typedef enum {Attente,FF,Size,Data} type_etat2; static type_etat2 etat2=Attente; //////////pc.printf("coucou"); //////pc.printf("%d\r\n", char_receive_serial2[valueserial2]); switch (etat2) { case Attente: if(char_receive_serial2[0] == 0xFF) { etat2 = FF; valueserial2 = 1; } break; case FF: if(char_receive_serial2[1] == 0xFF) { etat2 = Size; valueserial2 = 2; } else { etat2 = Attente; valueserial2 = 0; flag_perdu_info_serial2 = 1; //flag_perdu_info_serial1 } break; case Size: if(char_receive_serial2[2] < 7) { etat2 = Attente; valueserial2 = 0; flag_perdu_info_serial2 = 1; //flag_perdu_info_serial1 } else { etat2 = Data; old_valueserial2 = 2; valueserial2 = 3; } Size_trame_serial2 = char_receive_serial2[2]; break; case Data: if((valueserial2-2)==(Size_trame_serial2-3)) { flag_serial2_receive = 1; etat2 = Attente; valueserial2 = 0; } else { valueserial2++; } break; default: break; } } //---------------------fonction d'interruption de reception de serial3--------------------- //même principe que la fonction d'interrutpion de serial1 unsigned char flag_perdu_info_serial3 = 0, indicateur_serial3 = 0, Size_trame_serial3 = 0, old_valueserial3 = 0; unsigned char char_receive_serial3[100]; unsigned char valueserial3=0; unsigned char flag_serial3_receive=0; void receive_serial3() { char_receive_serial3[valueserial3]=serial3.getc(); automate_serial3(); } void Interrupt3_en(void) { serial3.attach(&receive_serial3,Serial::RxIrq); } void automate_serial3() { typedef enum {Attente,FF,Size,Data} type_etat3; static type_etat3 etat3=Attente; //////////pc.printf("coucou"); //////pc.printf("%d\r\n", char_receive_serial3[valueserial3]); switch (etat3) { case Attente: if(char_receive_serial3[0] == 0xFF) { etat3 = FF; valueserial3 = 1; } break; case FF: if(char_receive_serial3[1] == 0xFF) { etat3 = Size; valueserial3 = 2; } else { etat3 = Attente; valueserial3 = 0; flag_perdu_info_serial3 = 1; //flag_perdu_info_serial1 } break; case Size: if(char_receive_serial3[2] < 7) { etat3 = Attente; valueserial3 = 0; flag_perdu_info_serial3 = 1; //flag_perdu_info_serial1 } else { etat3 = Data; old_valueserial3 = 2; valueserial3 = 3; } Size_trame_serial3 = char_receive_serial3[2]; break; case Data: if((valueserial3-2)==(Size_trame_serial3-3)) { flag_serial3_receive = 1; etat3 = Attente; valueserial3 = 0; } else { valueserial3++; } break; default: break; } } //---------------------fonction d'interruption de reception de serial4--------------------- //même principe que la fonction d'interrutpion de serial1 unsigned char flag_perdu_info_serial4 = 0, indicateur_serial4 = 0, Size_trame_serial4 = 0, old_valueserial4 = 0; unsigned char char_receive_serial4[100]; unsigned char valueserial4=0; unsigned char flag_serial4_receive=0; void receive_serial4() { char_receive_serial4[valueserial4]=serial4.getc(); automate_serial4(); } void Interrupt4_en(void) { serial4.attach(&receive_serial4,Serial::RxIrq); } void automate_serial4() { typedef enum {Attente,FF,Size,Data} type_etat4; static type_etat4 etat4=Attente; //////////pc.printf("coucou"); //////pc.printf("%d\r\n", char_receive_serial4[valueserial4]); switch (etat4) { case Attente: if(char_receive_serial4[0] == 0xFF) { etat4 = FF; valueserial4 = 1; } break; case FF: if(char_receive_serial4[1] == 0xFF) { etat4 = Size; valueserial4 = 2; } else { etat4 = Attente; valueserial4 = 0; flag_perdu_info_serial4 = 1; //flag_perdu_info_serial1 } break; case Size: if(char_receive_serial4[2] < 7) { etat4 = Attente; valueserial4 = 0; flag_perdu_info_serial4 = 1; //flag_perdu_info_serial1 } else { etat4 = Data; old_valueserial4 = 2; valueserial4 = 3; } Size_trame_serial4 = char_receive_serial4[2]; break; case Data: if((valueserial4-2)==(Size_trame_serial4-3)) { flag_serial4_receive = 1; etat4 = Attente; valueserial4 = 0; } else { valueserial4++; } break; default: break; } } //---------------------fonction d'interruption de reception de serial5--------------------- //même principe que la fonction d'interrutpion de serial1 unsigned char flag_perdu_info_serial5 = 0, indicateur_serial5 = 0, Size_trame_serial5 = 0, old_valueserial5 = 0; unsigned char char_receive_serial5[100]; unsigned char valueserial5=0; unsigned char flag_serial5_receive=0; void receive_serial5() { char_receive_serial5[valueserial5]=serial5.getc(); automate_serial5(); } void Interrupt5_en(void) { serial5.attach(&receive_serial5,Serial::RxIrq); } void automate_serial5() { typedef enum {Attente,FF,Size,Data} type_etat5; static type_etat5 etat5=Attente; //////////pc.printf("coucou"); //////pc.printf("%d\r\n", char_receive_serial5[valueserial5]); switch (etat5) { case Attente: if(char_receive_serial5[0] == 0xFF) { etat5 = FF; valueserial5 = 1; } break; case FF: if(char_receive_serial5[1] == 0xFF) { etat5 = Size; valueserial5 = 2; } else { etat5 = Attente; valueserial5 = 0; flag_perdu_info_serial5 = 1; //flag_perdu_info_serial1 } break; case Size: if(char_receive_serial5[2] < 7) { etat5 = Attente; valueserial5 = 0; flag_perdu_info_serial5 = 1; //flag_perdu_info_serial1 } else { etat5 = Data; old_valueserial5 = 2; valueserial5 = 3; } Size_trame_serial5 = char_receive_serial5[2]; break; case Data: if((valueserial5-2)==(Size_trame_serial5-3)) { flag_serial5_receive = 1; etat5 = Attente; valueserial5 = 0; } else { valueserial5++; } break; default: break; } } //----------------xxxxx----fonction de fermture de serial----------------------- /*void N_Herkulex() { if(Sv != NULL) delete Sv; if(recevoir==2) { size_reponse = rx2[recevoir]; } }*/ //-------------------------fonction de transmission----------------------------- // //Permet de transmettre une trame manuellement sur une liaison série choisie // //packetSize ==> Taille totale de la trame en octets // en-têtes (HEADER) et données (data) inclus // //data ==> Données ( Ici il d'agit de la trame en entier) à rentrer sous forme de tableau (1 octet par case!) // //numero_serial ==> Numéro de la liaison série sur laquelle on // envoie la trame void txPacket(uint8_t packetSize, uint8_t* data, uint8_t numero_serial) /*#ifdef HERKULEX_DEBUG pc->printf("[TX]"); for(uint8_t i = 0; i < packetSize ; i++) { #ifdef HERKULEX_DEBUG pc->printf("%02X ",data[i]); #endif txd->putc(data[i]); } #ifdef HERKULEX_DEBUG pc->printf("\n"); #endif*/ { serial_numero = numero_serial; if(numero_serial == 1) { //Envoi sur la liaison série 1 for(uint8_t i = 0; i < packetSize ; i++) { // while(serial1.writeable() == 0); //On envoie 1 octet toute les 100 us serial1.putc(data[i]); // wait_us(100); // } } else if(numero_serial == 2) { //Envoi sur la liaison série 2 for(uint8_t i = 0; i < packetSize ; i++) { while(serial2.writeable() == 0); serial2.putc(data[i]); wait_us(100); } } else if(numero_serial == 3) { //Envoi sur la liaison série 3 for(uint8_t i = 0; i < packetSize ; i++) { while(serial3.writeable() == 0); serial3.putc(data[i]); wait_us(100); } } else if(numero_serial == 4) { //Envoi sur la liaison série 4 for(uint8_t i = 0; i < packetSize ; i++) { while(serial4.writeable() == 0); serial4.putc(data[i]); wait_us(100); } } else if(numero_serial == 5) { //Envoi sur la liaison série 5 for(uint8_t i = 0; i < packetSize ; i++) { while(serial5.writeable() == 0); serial5.putc(data[i]); wait_us(100); } } wait_ms(TEMPO_R); } //----------------------------fonction de reception----------------------------- //Permet de recevoir une trame void rxPacket(uint8_t packetSize, uint8_t* data, uint8_t numero_serial) // //packetSize ==> taille de la trame à recevoir //data ==> Données // { /*#ifdef HERKULEX_DEBUG pc->printf("[RX]"); #endif for (uint8_t i=0; i < packetSize; i++) { data[i] = rxd->getc(); #ifdef HERKULEX_DEBUG pc->printf("%02X ",data[i]); #endif } #ifdef HERKULEX_DEBUG pc->printf("\n"); #endif*/ serial_numero = numero_serial; if(numero_serial == 1) { if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { data[i4] = char_receive_serial1[i4]; //////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { data[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { data[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { data[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { data[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } } //----------------------fonction pour sortir de l'état d'erreur------------------------- // //Permet de "sortir" de la mise en erreur d'un servomoteur // void clear(uint8_t id, uint8_t numero_serial) // // id ==> On entre l'ID du servomoteur que l'on souhaite sortir de l'état d'erreur // numero serial ==> On entre le numéro de la liaison série sur laquelle se trouve le servomoteur concerné { uint8_t txBuf[11]; serial_numero = numero_serial; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 4; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_WRITE; // Command Ram Write (0x03) *On choisi le CMD pour écrire dans un registre txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_STATUS_ERROR; // Address *On écrit dans le registre RAM_STATUS_ERROR txBuf[8] = BYTE2; // Length * txBuf[9] = 0; // Clear RAM_STATUS_ERROR txBuf[10]= 0; // Clear RAM_STATUS_DETAIL // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]^txBuf[10]) & 0xFE; //calcul de checksum1 txBuf[6] = (~txBuf[5])&0xFE; //calcul de checksum2 // send packet (mbed -> herkulex) if(numero_serial == 1) { for(uint8_t i = 0; i < 11 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 11 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 11 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 11 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 11 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } wait_ms(TEMPO_R); } //----------------fonction de mise à jour du couple du servo--------------------- void setTorque(uint8_t id, uint8_t cmdTorque, uint8_t numero_serial) // Permet de modifier l'état du couple d'un servo------------ // id ==> ID du servomoteur //cmdTorque ==> état souhaité pour le couple //numero_serial ==> Numéro de la liaison série sur laquelle se trouve le servo // valeurs posssibles pour cmdTorque // 0x40 Break On Opérations commandes impossibles // 0x60 Torque On Fontionnement normal // 0x00 Torque Free Opérations commandes impossibles + possibilité de déplacer le servo manuellement { uint8_t txBuf[10]; serial_numero = numero_serial; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 3; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_WRITE; // Command Ram Write (0x03) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_TORQUE_CONTROL; // Address txBuf[8] = BYTE1; // Length txBuf[9] = cmdTorque; // Torque ON // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) if(numero_serial == 1) { for(uint8_t i = 0; i < 10 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 10 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 10 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 10 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 10 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } wait_ms(TEMPO_R); } //-------------fonction de contrôle de position pour un seul servo-------------- //Permet de controler un servomoteur en position void positionControl(uint8_t id, uint16_t position, uint8_t playtime, uint8_t setLED, uint8_t numero_serial) // //id ==> id du servo à déplacer //position ==> position à atteindre //playtime ==> temps à mettre pour effectuer le déplacement //setLED ==> LED à allumer //numero-serial ==> numéro de la liaison série { float tempo=0; serial_numero = numero_serial; //if (position > 1023) return; //1002-21 if (playtime > 254) playtime = 254; //return; //1-254 == 11.2ms-2.844sec. tempo=playtime*0.012; pos_ID = id; uint8_t txBuf[12]; etat = pos; pos_position = position; pos_time = playtime; pos_led = setLED; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 5; // Packet Size //txBuf[3] = MAX_PID; txBuf[3] = id; // pID is total number of servos in the network (0 ~ 253) txBuf[4] = CMD_S_JOG; // Command S JOG (0x06) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = playtime; // Playtime txBuf[8] = position & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[9] =(position & 0xFF00) >> 8; // position (MSB, Most Significanct Bit) txBuf[10] = POS_MODE | setLED; // Pos Mode and LED on/off txBuf[11] = id; // Servo ID // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]^txBuf[10]^txBuf[11]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) //txPacket(12, txBuf); if(numero_serial == 1) { for(uint8_t i = 0; i < 12 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); //pc.printf("%d/",txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 12 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 12 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 12 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 12 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } wait(tempo); wait_ms(TEMPO_R); } //-------------fonction de controle de vitesse pour un seul servo--------------- void velocityControl(uint8_t id, int16_t speed, uint8_t setLED, uint8_t numero_serial) // //id ==> id du servo à déplacer //speed ==> vitesse (sans dec) //setLED ==> LED à allumer //numero_serial ==> numéro de la liaison série // { serial_numero = numero_serial; if (speed > 1023 || speed < -1023) return; uint8_t txBuf[12]; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 5; // Packet Size txBuf[3] = id; // pID is total number of servos in the network (0 ~ 253) txBuf[4] = CMD_S_JOG; // Command S JOG (0x06) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = 0; // Playtime, unmeaningful in turn mode if (speed >= 0) { //On gère la vitesse positive txBuf[8] = speed & 0x00FF; // Speed (LSB, Least Significant Bit) txBuf[9] =(speed & 0xFF00) >> 8; // Speed (MSB, Most Significanct Bit) } else if(speed < 0) { //On gère la vitesse négative (voir pg.48 de la documentation herkulex) speed= abs(speed); txBuf[8] = speed & 0x00FF; // Speed (LSB, Least Significant Bit) txBuf[9] =((speed|0x4000) & 0xFF00) >> 8; // Speed (MSB, Most Significanct Bit) } txBuf[10] = TURN_MODE | setLED; // Turn Mode and LED on/off txBuf[11] = id; // Servo ID // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]^txBuf[10]^txBuf[11]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) if(numero_serial == 1) { txPacket(12, txBuf,1); } else if(numero_serial == 2) { txPacket(12, txBuf,2); } else if(numero_serial == 3) { txPacket(12, txBuf,3); } else if(numero_serial == 4) { txPacket(12, txBuf,4); } else if(numero_serial == 5) { txPacket(12, txBuf,5); } wait_ms(TEMPO_R); } //--------------------Compteur de tour------------------------------------------------------------------------ //c'est un compteur de tour (CQFD) void compteTour(int ID,int16_t speed,uint8_t tour, uint16_t position,uint8_t setLED,uint8_t serial) // //id ==> id du servo à déplacer //speed ==> vitesse //tour ==> nombre de tour à effectuer //position ==> position finale //setLED ==> LED à allumer //numero_serial ==> numéro de la liaison série // // { int etat =0; int flagTour=0; int flagDernierTour = 0; int end = 0; int posAct, posCible, pos; servo_interrupt_en(); clear(ID,serial); setTorque(ID, TORQUE_ON,serial); posCible=getPos(ID,serial);//position; //pc.printf("\nPos depart :%d",posCible); velocityControl(ID,speed,setLED,serial); wait_ms(100); if(tour == 0){ etat = 2; tour = 1; } if(speed > 0) { while(end != 1) { switch (etat) { case 0 : pos = getPos(ID,serial); posAct = pos - posCible; if(posAct<0){ //pc.printf("\n0 pos :%d",pos); clear(ID,serial); setTorque(ID, TORQUE_ON,serial); etat=1; } break; case 1 : pos = getPos(ID,serial); velocityControl(ID,speed,RLED_ON,serial); posAct = posCible - pos; if (posAct < 0 ){ //pc.printf("\n1 pos :%d",pos); etat = 2; } break; case 2 : clear(ID,serial); setTorque(ID, TORQUE_ON,serial); if (flagTour == tour-1) { if (getPos(ID,serial) > position && !flagDernierTour){ //pc.printf("\nTour sup"); // flagTour++; flagDernierTour =1; etat =0; posCible = position; }else{ //pc.printf("\ngoto pos finale"); velocityControl(ID,0,setLED,serial); positionControl(ID,position,1,setLED,serial); end = 1; } } else { flagTour=flagTour+1; //pc.printf("\ntours execute : %d",flagTour); etat = 0; } break; } } } else if(speed < 0) { while(end != 1) { switch (etat) { case 0 : pos = getPos(ID,serial); posAct = pos - posCible; if(posAct>0){ //pc.printf("\n0 pos :%d",pos); clear(ID,serial); setTorque(ID, TORQUE_ON,serial); etat=1; } break; case 1 : pos = getPos(ID,serial); velocityControl(ID,speed,RLED_ON,serial); posAct = posCible - pos; if (posAct > 0 ){ //pc.printf("\n1 pos :%d",pos); etat = 2; } break; case 2 : clear(ID,serial); setTorque(ID, TORQUE_ON,serial); if (flagTour == tour-1) { if (getPos(ID,serial) < position && !flagDernierTour){ //pc.printf("\nTour sup"); // flagTour++; flagDernierTour =1; etat =0; posCible = position; }else{ //pc.printf("\ngoto pos finale"); velocityControl(ID,0,setLED,serial); positionControl(ID,position,1,setLED,serial); end = 1; } } else { flagTour=flagTour+1; //pc.printf("\ntours execute : %d",flagTour); etat = 0; } break; } } } } /* { int etat =0; int flagTour=0; int end = 0; int posAct, posCible; servo_interrupt_en(); clear(ID,serial); setTorque(ID, TORQUE_ON,serial); posCible=position; velocityControl(ID,speed,setLED,serial); wait_ms(100); if(speed > 0) { while(end != 1) { switch (etat) { case 0 : posAct = getPos(ID,serial); posAct = posAct-posCible; //pc.printf("%d",posAct); if (posAct < 0) { clear(ID,serial); setTorque(ID, TORQUE_ON,serial); etat=1; } break; case 1 : velocityControl(ID,speed,RLED_ON,serial); posAct = getPos(ID,serial); posAct = posCible-posAct; if (posAct < 0) etat = 2; break; case 2 : clear(ID,serial); setTorque(ID, TORQUE_ON,serial); if (flagTour == tour-1 | tour == 0) { velocityControl(ID,0,setLED,serial); positionControl(ID,posCible,1,setLED,serial); end = 1; } else { flagTour=flagTour+1; etat = 0; } break; } } } else if(speed < 0) { while(end != 1) { switch (etat) { case 0 : posAct = getPos(ID,serial); posAct = posCible-posAct; //pc.printf("%d",posAct); if (posAct < 0) { clear(ID,serial); setTorque(ID, TORQUE_ON,serial); etat=1; } break; case 1 : velocityControl(ID,speed,RLED_ON,serial); posAct = getPos(ID,serial); posAct = posAct-posCible; if (posAct < 0) etat = 2; break; case 2 : clear(ID,serial); setTorque(ID, TORQUE_ON,serial); if (flagTour == tour-1 | tour == 0) { velocityControl(ID,0,setLED,serial); positionControl(ID,posCible,1,setLED,serial); end =1; } else { flagTour=flagTour+1; etat = 0; } break; } } } }*/ //--------------------fonction d'acquisition d'etat d'un servo----------------------- int8_t getStatus(uint8_t id, uint8_t numero_serial) // // renvoi l'état du servomoteur (doc pg 39) // //id ==> Id du servo concerné //numero-serial ==> numéro de la liaison série du servo // { serial_numero = numero_serial; uint8_t status; uint8_t txBuf[7]; size_reponse = 9; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_STAT; // Status Error, Status Detail request // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; uint8_t rxBuf[9]; if(numero_serial == 1) { for(uint8_t i = 0; i < 7 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; ////////////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 7 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 7 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 7 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 7 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } // Checksum1 uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]) & 0xFE; if (chksum1 != rxBuf[5]) { if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } // Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } status = rxBuf[7]; // Status Error //status = rxBuf[8]; // Status Detail return status; } //------------------fonction pour lire la position actuelle----------------------- int16_t getPos(uint8_t id, uint8_t numero_serial) // //renvoie la position d'un servo // //!!!ne pas oublier d'utiliser servo_interrupt_en();!!! // //id ==> id d'un servomoteur //numero_serial==> numéro de la liaison série du servo // { serial_numero = numero_serial; uint16_t position = 0; uint8_t txBuf[9]; size_reponse = 13; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 2; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_READ; // Command Ram Read txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_CALIBRATED_POSITION; // Address txBuf[8] = BYTE2; // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; uint8_t rxBuf[13]; if(numero_serial == 1) { for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; //pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 9 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 9 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 9 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 9 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } // Checksum1 uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]^rxBuf[9]^rxBuf[10]^rxBuf[11]^rxBuf[12]) & 0xFE; if (chksum1 != rxBuf[5]) { /*#ifdef HERKULEX_DEBUG pc->printf("Checksum1 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { /* #ifdef HERKULEX_DEBUG pc->printf("Checksum2 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } position = ((rxBuf[10]&0x03)<<8) | rxBuf[9]; //} return position; } //---------------fonction d'acquis d'etat de couple d'un servo------------------ //Obtenir la valeur du couple d'un servo int8_t Get_Torque(int8_t id, uint8_t numero_serial) // //id ==> id du servomoteur sur la liaison série //numero_serial ==> numéro de la liaison série sur laquelle se trouve le servomoteur // { serial_numero = numero_serial; uint8_t txBuf[9]; int8_t Tor = 0; uint8_t iv=0; for(iv=0; iv<20; iv++) { rx2[iv] = 0; } txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 2; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_READ; // Command Ram Read txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_TORQUE_CONTROL; txBuf[8] = BYTE1; // Length txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]) & 0xFE;//Checksum2 txBuf[6] = (~txBuf[5])&0xFE; // CheckSum2 //pc.printf(" Torque "); uint8_t rxBuf[12]; if(numero_serial == 1) { //send packet (mbed -> herkulex) for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } //send packet (mbed -> herkulex) //uint8_t rxBuf[12]; wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; //////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 9 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 9 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 9 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 9 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]^rxBuf[9]^rxBuf[10]^rxBuf[11]) & 0xFE; if (chksum1 != rxBuf[5]) { /*#ifdef HERKULEX_DEBUG pc->printf("Checksum1 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { /* #ifdef HERKULEX_DEBUG pc->printf("Checksum2 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } Tor = rxBuf[9]; /* #ifdef HERKULEX_DEBUG pc->printf("position = %04X(%d)\n", position, position); #endif*/ //} return Tor; } //---------------fonction pour lire le temperature max pour un servo------------ //obtenir la valeur de température maximum tolérée par le servomoteur int8_t Get_Temperature_MAX(int8_t id, uint8_t numero_serial) // //id ==> id du servomoteur sur la liaison série //numero_serial ==> numéro de la liaison série sur laquelle se trouve le servomoteur // { serial_numero = numero_serial; uint8_t txBuf[9]; int8_t tempeMAX = 0; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 2; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_READ; // Command Ram Read txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_MAX_TEMPERATURE; txBuf[8] = BYTE1; // Length // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; //pc.printf(" tempeMAX "); uint8_t rxBuf[12]; if(numero_serial == 1) { //send packet (mbed -> herkulex) for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } //send packet (mbed -> herkulex) //uint8_t rxBuf[12]; wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; //////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 9 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 9 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 9 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 9 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]^rxBuf[9]^rxBuf[10]^rxBuf[11]) & 0xFE; if (chksum1 != rxBuf[5]) { /*#ifdef HERKULEX_DEBUG pc->printf("Checksum1 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { /* #ifdef HERKULEX_DEBUG pc->printf("Checksum2 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } tempeMAX = rxBuf[9]; /* #ifdef HERKULEX_DEBUG pc->printf("position = %04X(%d)\n", position, position); #endif*/ //} return tempeMAX; } //--------fonction de controle de position pour deux servo(same playtime)------- //permet de déplacer deux servomoteurs sur la même liaison série avec le même temps d'execution void positionControl_Mul_ensemble(uint8_t id, uint16_t position, uint8_t playtime, uint8_t setLED,uint8_t id2, uint16_t position2, uint8_t setLED2, uint8_t numero_serial) // //id // { serial_numero = numero_serial; float tempo=0; //if (position > 1023) return; //1002-21 if (playtime > 254) return; //1-254 == 11.2ms-2.844sec. tempo=playtime*0.012; uint8_t txBuf[16]; etat = pos; pos_position = position; pos_time = playtime; pos_led = setLED; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 9; // Packet Size //txBuf[3] = MAX_PID; // pID is total number of servos in the network (0 ~ 253) txBuf[3] = 254; // broadcast ID txBuf[4] = CMD_S_JOG; // Command S JOG (0x06) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = playtime; // Playtime txBuf[8] = position & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[9] =(position & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) txBuf[10] = POS_MODE | setLED; // Pos Mode and LED on/off txBuf[11] = id; // Servo ID txBuf[12] = position2 & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[13] =(position2 & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) txBuf[14] = POS_MODE | setLED2; // Pos Mode and LED on/off txBuf[15] = id2; // Servo ID // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]^txBuf[10]^txBuf[11]^txBuf[12]^txBuf[13]^txBuf[14]^txBuf[15]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) if(numero_serial == 1) { for(uint8_t i = 0; i < 16 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 16 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 16 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 16 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 16 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } wait(tempo); wait_ms(TEMPO_R); } //-----fonction de controle de position pour deux servo(different playtime)----- //a changer... void positionControl_Mul_playtime_different(uint8_t id, uint16_t position, uint8_t playtime, uint8_t setLED,uint8_t id2, uint16_t position2, uint8_t playtime2, uint8_t setLED2, uint8_t numero_serial) // //permet de controler deux servomoteurs avec des temps d'execution différents // { serial_numero = numero_serial; float tempo=0; //if (position > 1023) return; //1002-21 if (playtime > 254) playtime = 254; //return; //1-254 == 11.2ms-2.844sec. if(playtime>playtime2) { tempo=playtime*0.012; } else if(playtime<playtime2) { tempo=playtime2*0.012; } uint8_t txBuf[17]; etat = pos; pos_position = position; pos_time = playtime; pos_led = setLED; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 9; // Packet Size //txBuf[3] = MAX_PID; // pID is total number of servos in the network (0 ~ 253) txBuf[3] = 254; // broadcast ID txBuf[4] = CMD_I_JOG; // Command I JOG txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = position & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[8] =(position & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) txBuf[9] = POS_MODE | setLED; // Pos Mode and LED on/off txBuf[10] = id; // Servo ID txBuf[11] = playtime; // Playtime txBuf[12] = position2 & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[13] =(position2 & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) txBuf[14] = POS_MODE | setLED2; // Pos Mode and LED on/off txBuf[15] = id2; // Servo ID txBuf[16] = playtime2; // Playtime // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]^txBuf[10]^txBuf[11]^txBuf[12]^txBuf[13]^txBuf[14]^txBuf[15]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) //txPacket(12, txBuf); if(numero_serial == 1) { for(uint8_t i = 0; i < 17 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 17 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 17 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 17 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 17 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } wait_ms(TEMPO_R); } //-----fonction de controle de position pour plusieurs servo(same playtime)----- void positionControl_Mul_ensemble_complex(uint8_t nb_servo, uint8_t playtime, uint8_t* data, uint16_t* pos, uint8_t numero_serial) // uint16_t position, uint8_t setLED, uint8_t id // //Permet de controler tout les servos de la même liaison série avec le même temps d'execution // // { serial_numero = numero_serial; //float tempo=0; uint8_t taille = 0,i = 0,idata = 0, ipos = 0; //if (position > 1023) return; //1002-21 if (playtime > 254) return; //1-254 == 11.2ms-2.844sec. //tempo=playtime*0.012; taille = 7 + 1 + 4 * nb_servo; nombre_servo = nb_servo; pos_time = playtime; uint8_t txBuf[taille]; etat = pos_mul_complex; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 1 + 4 * nb_servo; // Packet Size //txBuf[3] = MAX_PID; // pID is total number of servos in the network (0 ~ 253) txBuf[3] = 254; // broadcast ID txBuf[4] = CMD_S_JOG; // Command S JOG (0x06) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = playtime; // Playtime for(i=0; i<nb_servo; i++) { txBuf[8+i*4] = pos[ipos] & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[9+i*4] =(pos[ipos] & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) position_servo_mul[ipos] = pos[ipos]; ipos++; txBuf[10+i*4] = POS_MODE | data[idata]; // Pos Mode and LED on/off data_servo_mul[idata] = data[idata]; idata++; txBuf[11+i*4] = data[idata]; // Servo ID data_servo_mul[idata] = data[idata]; idata++; } // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]; for(i=1; i<(taille-7); i++) { txBuf[5]=txBuf[5]^txBuf[7+i]; } txBuf[5] = txBuf[5]& 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) if(numero_serial == 1) { for(uint8_t i = 0; i < taille ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < taille ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < taille ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < taille ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < taille ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } /*for(uint8_t i = 0; i < taille ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); }*/ wait_ms(TEMPO_R); } //--fonction de controle de position pour plusieurs servo(different playtime)--- void positionControl_Mul_ensemble_different_complex(uint8_t nb_servo, uint8_t* data, uint16_t* pos, uint8_t numero_serial) // uint16_t position, uint8_t setLED, uint8_t id, uint8_t playtime // //Permet de controler tout les servos de la même liaison série avec un temps d'execution différent // { serial_numero = numero_serial; float tempo=0; uint8_t Max_playtime = 0; uint8_t taille = 0,i = 0,idata = 0, ipos = 0,iplay_time = 0; //if (position > 1023) return; //1002-21 //if (playtime > 254) return; //1-254 == 11.2ms-2.844sec. for(iplay_time=0; iplay_time<nb_servo; iplay_time++) { if(Max_playtime<data[2+3*iplay_time]) { Max_playtime=data[2+3*iplay_time]; } } tempo=Max_playtime*0.012; taille = 7 + 5 * nb_servo; nombre_servo = nb_servo; uint8_t txBuf[taille]; etat = pos_mul_complex_different; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 5 * nb_servo; // Packet Size //txBuf[3] = MAX_PID; // pID is total number of servos in the network (0 ~ 253) txBuf[3] = 254; // broadcast ID txBuf[4] = CMD_I_JOG; // Command I JOG (0x06) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 for(i=0; i<nb_servo; i++) { txBuf[7+i*5] = pos[ipos] & 0x00FF; // Position (LSB, Least Significant Bit) txBuf[8+i*5] =(pos[ipos] & 0xFF00) >> 8;// position (MSB, Most Significanct Bit) position_servo_mul_different[ipos] = pos[ipos]; ipos++; txBuf[9+i*5] = POS_MODE | data[idata]; // Pos Mode and LED on/off data_servo_mul_different[idata] = data[idata]; idata++; txBuf[10+i*5] = data[idata]; // Servo ID data_servo_mul_different[idata] = data[idata]; idata++; txBuf[11+i*5] = data[idata]; // Playtime data_servo_mul_different[idata] = data[idata]; idata++; } // Checksum1 = (PacketSize ^ pID ^ CMD ^ Data[0] ^ Data[1] ^ ... ^ Data[n]) & 0xFE // Checksum2 = (~Checksum1)&0xFE txBuf[5] = txBuf[2]^txBuf[3]^txBuf[4]; for(i=1; i<(taille-6); i++) { txBuf[5]=txBuf[5]^txBuf[6+i]; } txBuf[5] = txBuf[5]& 0xFE; txBuf[6] = (~txBuf[5])&0xFE; // send packet (mbed -> herkulex) if(numero_serial == 1) { for(uint8_t i = 0; i < taille ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < taille ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < taille ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < taille ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < taille ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } /*for(uint8_t i = 0; i < taille ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); }*/ wait(tempo); wait_ms(TEMPO_R); } //---------------fonction pour lire la tension minimale pour un servo---------------- int8_t Get_Tension_MIN(int8_t id, uint8_t numero_serial) { serial_numero = numero_serial; uint8_t txBuf[9]; int8_t tensionMIN = 0; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 2; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_READ; // Command Ram Read txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_MIN_VOLTAGE; txBuf[8] = BYTE1; // Length // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; //pc.printf(" tensionMIN "); uint8_t rxBuf[12]; if(numero_serial == 1) { //send packet (mbed -> herkulex) for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } //send packet (mbed -> herkulex) //uint8_t rxBuf[12]; wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; //////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 9 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 9 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 9 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 9 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } /*for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } // send packet (mbed -> herkulex) uint8_t rxBuf[12]; //wait_ms(3); wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0;i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; ////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; }*/ uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]^rxBuf[9]^rxBuf[10]^rxBuf[11]) & 0xFE; if (chksum1 != rxBuf[5]) { /*#ifdef HERKULEX_DEBUG pc->printf("Checksum1 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { /* #ifdef HERKULEX_DEBUG pc->printf("Checksum2 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } tensionMIN = rxBuf[9]; /* #ifdef HERKULEX_DEBUG pc->printf("position = %04X(%d)\n", position, position); #endif*/ //} return tensionMIN; } //-------------fonction pour controle la tension min pour un servo-------------- void Set_Tension_MIN(int8_t id,uint8_t Tension_Min, uint8_t numero_serial) { serial_numero = numero_serial; uint8_t txBuf[10]; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 3; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_WRITE; // Command Ram Write (0x03) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_MIN_VOLTAGE; txBuf[8] = BYTE1; // Length txBuf[9] = Tension_Min; // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]^txBuf[9]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; //pc.printf(" tensionMIN "); /*for(uint8_t i = 0; i < 10 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); }*/ if(numero_serial == 1) { for(uint8_t i = 0; i < 10 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 10 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 10 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 10 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 10 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } } //wait_ms(3); wait_ms(TEMPO_R); } //------------fonction pour lire la tension d'un servo------------- int8_t Get_Tension_actuelle(int8_t id, uint8_t numero_serial) { serial_numero = numero_serial; uint8_t txBuf[9]; int8_t tension = 0; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = MIN_PACKET_SIZE + 2; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = CMD_RAM_READ; // Command Ram Read (0x03) txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 txBuf[7] = RAM_VOLTAGE; txBuf[8] = BYTE2; // Length // Check Sum1 and Check Sum2 txBuf[5] = (txBuf[2]^txBuf[3]^txBuf[4]^txBuf[7]^txBuf[8]) & 0xFE; txBuf[6] = (~txBuf[5])&0xFE; //pc.printf(" tension "); uint8_t rxBuf[13]; if(numero_serial == 1) { //send packet (mbed -> herkulex) for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } //send packet (mbed -> herkulex) //uint8_t rxBuf[13]; wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; //////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 9 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<Size_trame_serial2; i4++) { rxBuf[i4] = char_receive_serial2[i4]; //////pc.printf("%d ",(int)char_receive_serial2[i4]); } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 9 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<Size_trame_serial3; i4++) { rxBuf[i4] = char_receive_serial3[i4]; //////pc.printf("%d ",(int)char_receive_serial3[i4]); } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 9 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<Size_trame_serial4; i4++) { rxBuf[i4] = char_receive_serial4[i4]; //////pc.printf("%d ",(int)char_receive_serial4[i4]); } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 9 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<Size_trame_serial5; i4++) { rxBuf[i4] = char_receive_serial5[i4]; //////pc.printf("%d ",(int)char_receive_serial5[i4]); } flag_serial5_receive=0; valueserial5=0; } } /* for(uint8_t i = 0; i < 9 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } // send packet (mbed -> herkulex) uint8_t rxBuf[13]; //wait_ms(3); wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0;i4<Size_trame_serial1; i4++) { rxBuf[i4] = char_receive_serial1[i4]; ////pc.printf("%d ",(int)char_receive_serial1[i4]); } flag_serial1_receive=0; valueserial1=0; } */ uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]^rxBuf[8]^rxBuf[9]^rxBuf[10]^rxBuf[11]^rxBuf[12]) & 0xFE; if (chksum1 != rxBuf[5]) { /*#ifdef HERKULEX_DEBUG pc->printf("Checksum1 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { /* #ifdef HERKULEX_DEBUG pc->printf("Checksum2 fault\n"); #endif*/ if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } tension = rxBuf[9]; /* #ifdef HERKULEX_DEBUG pc->printf("position = %04X(%d)\n", position, position); #endif*/ //} return tension; } //----------------------------------------------------------------------------------------- void servo_interrupt_en(void) { Interrupt1_en(); Interrupt2_en(); Interrupt3_en(); Interrupt4_en(); Interrupt5_en(); } int8_t Get_Led(uint8_t id, uint8_t numero_serie) { char numero_serial = numero_serie; uint8_t txBuf[7]; txBuf[0] = HEADER; // Packet Header (0xFF) txBuf[1] = HEADER; // Packet Header (0xFF) txBuf[2] = 0x07; // Packet Size txBuf[3] = id; // Servo ID txBuf[4] = 0x05; // Command Ram Write (0x03) *On choisi le CMD pour écrire dans un registre txBuf[5] = 0; // Checksum1 txBuf[6] = 0; // Checksum2 // calcul des checksums // txBuf[5]=(txBuf[2]^txBuf[3]^txBuf[4]) & 0xFE; // checksum1 txBuf[5] &= 0xFE; // checksum1 txBuf[6] = (~txBuf[5] & 0xFE);//checksum2 // envoi // //txPacket(0x07,txBuf,numero_serial); //reception uint8_t rxBuf[9]; if(numero_serial == 1) { for(uint8_t i = 0; i < 7 ; i++) { while(serial1.writeable() == 0); serial1.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial1_receive) { for(unsigned char i4=0; i4<8; i4++) { rxBuf[i4] = char_receive_serial1[i4]; } flag_serial1_receive=0; valueserial1=0; } } else if(numero_serial == 2) { for(uint8_t i = 0; i < 7 ; i++) { while(serial2.writeable() == 0); serial2.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial2_receive) { for(unsigned char i4=0; i4<8; i4++) { rxBuf[i4] = char_receive_serial2[i4]; } flag_serial2_receive=0; valueserial2=0; } } else if(numero_serial == 3) { for(uint8_t i = 0; i < 7 ; i++) { while(serial3.writeable() == 0); serial3.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial3_receive) { for(unsigned char i4=0; i4<8; i4++) { rxBuf[i4] = char_receive_serial3[i4]; } flag_serial3_receive=0; valueserial3=0; } } else if(numero_serial == 4) { for(uint8_t i = 0; i < 7 ; i++) { while(serial4.writeable() == 0); serial4.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial4_receive) { for(unsigned char i4=0; i4<8; i4++) { rxBuf[i4] = char_receive_serial4[i4]; } flag_serial4_receive=0; valueserial4=0; } } else if(numero_serial == 5) { for(uint8_t i = 0; i < 7 ; i++) { while(serial5.writeable() == 0); serial5.putc(txBuf[i]); wait_us(100); } wait_ms(TEMPO_R); if(flag_serial5_receive) { for(unsigned char i4=0; i4<8; i4++) { rxBuf[i4] = char_receive_serial5[i4]; } flag_serial5_receive=0; valueserial5=0; } } // Checksum1 uint8_t chksum1 = (rxBuf[2]^rxBuf[3]^rxBuf[4]^rxBuf[7]) & 0xFE; if (chksum1 != rxBuf[5]) { if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; }// Checksum2 uint8_t chksum2 = (~rxBuf[5]&0xFE); if (chksum2 != rxBuf[6]) { if(numero_serial == 1) { flag_serial1_receive=0; } else if(numero_serial == 2) { flag_serial2_receive=0; } else if(numero_serial == 3) { flag_serial3_receive=0; } else if(numero_serial == 4) { flag_serial4_receive=0; } else if(numero_serial == 5) { flag_serial5_receive=0; } return -1; } int8_t couleur_hrk = rxBuf[7]; // Couleur return couleur_hrk; }