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main.cpp
- Committer:
- Lightvalve
- Date:
- 2021-01-06
- Revision:
- 245:3592e0da43fb
- Parent:
- 244:b8e9935406dd
- Child:
- 246:d483d039ca55
File content as of revision 245:3592e0da43fb:
//210106_3 500Hz num_input 12 210105 data #include "mbed.h" #include "FastPWM.h" #include "INIT_HW.h" #include "function_CAN.h" #include "SPI_EEP_ENC.h" #include "I2C_AS5510.h" #include "setting.h" #include "function_utilities.h" #include "stm32f4xx_flash.h" #include "FlashWriter.h" #include <string> #include <iostream> #include <cmath> using namespace std; Timer t; ///191008//// // dac & check /////////////////////////////////////////// DigitalOut check(PC_2); DigitalOut check_2(PC_3); AnalogOut dac_1(PA_4); AnalogOut dac_2(PA_5); AnalogIn adc1(PC_4); //pressure_1 AnalogIn adc2(PB_0); //pressure_2 AnalogIn adc3(PC_1); //current // PWM /////////////////////////////////////////// float dtc_v=0.0f; float dtc_w=0.0f; // I2C /////////////////////////////////////////// I2C i2c(PC_9,PA_8); // SDA, SCL (for K22F) const int i2c_slave_addr1 = 0x56; unsigned int value; // 10bit output of reading sensor AS5510 // SPI /////////////////////////////////////////// SPI eeprom(PB_15, PB_14, PB_13); // EEPROM //(SPI_MOSI, SPI_MISO, SPI_SCK); DigitalOut eeprom_cs(PB_12); //FlashWriter writer(6);//2부터 7까지 되는듯 아마 sector SPI enc(PC_12,PC_11,PC_10); DigitalOut enc_cs(PD_2); DigitalOut LED(PA_15); // UART /////////////////////////////////////////// Serial pc(PA_9,PA_10); // _ UART // CAN /////////////////////////////////////////// CAN can(PB_8, PB_9, 1000000); CANMessage msg; void onMsgReceived() { CAN_RX_HANDLER(); } // Variables /////////////////////////////////////////// State pos; State vel; State Vout; State torq; State torq_dot; State pres_A; State pres_B; State cur; State valve_pos; State INIT_Vout; State INIT_Valve_Pos; State INIT_Pos; State INIT_torq; extern int CID_RX_CMD; extern int CID_RX_REF_POSITION; extern int CID_RX_REF_VALVE_POS; extern int CID_RX_REF_PWM; extern int CID_TX_INFO; extern int CID_TX_POSITION; extern int CID_TX_TORQUE; extern int CID_TX_PRES; extern int CID_TX_VOUT; extern int CID_TX_VALVE_POSITION; // ============================================================================= // ============================================================================= // ============================================================================= /******************************************************************************* * REFERENCE MODE ******************************************************************************/ enum _REFERENCE_MODE { MODE_REF_NO_ACT = 0, //0 MODE_REF_DIRECT, //1 MODE_REF_COS_INC, //2 MODE_REF_LINE_INC, //3 MODE_REF_SIN_WAVE, //4 MODE_REF_SQUARE_WAVE, //5 }; /******************************************************************************* * CONTROL MODE ******************************************************************************/ enum _CONTROL_MODE { //control mode MODE_NO_ACT = 0, //0 MODE_VALVE_POSITION_CONTROL, //1 MODE_JOINT_CONTROL, //2 MODE_VALVE_OPEN_LOOP, //3 MODE_JOINT_ADAPTIVE_BACKSTEPPING, //4 MODE_RL, //5 MODE_JOINT_POSITION_PRES_CONTROL_PWM, //6 MODE_JOINT_POSITION_PRES_CONTROL_VALVE_POSITION, //7 MODE_VALVE_POSITION_PRES_CONTROL_LEARNING, //8 MODE_TEST_CURRENT_CONTROL, //9 MODE_TEST_PWM_CONTROL, //10 MODE_CURRENT_CONTROL, //11 MODE_JOINT_POSITION_TORQUE_CONTROL_CURRENT, //12 MODE_JOINT_POSITION_PRES_CONTROL_CURRENT, //13 MODE_VALVE_POSITION_TORQUE_CONTROL_LEARNING, //14 //utility MODE_TORQUE_SENSOR_NULLING = 20, //20 MODE_VALVE_NULLING_AND_DEADZONE_SETTING, //21 MODE_FIND_HOME, //22 MODE_VALVE_GAIN_SETTING, //23 MODE_PRESSURE_SENSOR_NULLING, //24 MODE_PRESSURE_SENSOR_CALIB, //25 MODE_ROTARY_FRICTION_TUNING, //26 MODE_DDV_POS_VS_PWM_ID = 30, //30 MODE_DDV_DEADZONE_AND_CENTER, //31 MODE_DDV_POS_VS_FLOWRATE, //32 MODE_SYSTEM_ID, //33 MODE_FREQ_TEST, //34 MODE_SEND_BUFFER, //35 MODE_SEND_OVER, //36 MODE_STEP_TEST, //37 }; void SystemClock_Config(void) { RCC_OscInitTypeDef RCC_OscInitStruct = {0}; RCC_ClkInitTypeDef RCC_ClkInitStruct = {0}; /** Configure the main internal regulator output voltage */ __HAL_RCC_PWR_CLK_ENABLE(); __HAL_PWR_VOLTAGESCALING_CONFIG(PWR_REGULATOR_VOLTAGE_SCALE1); /** Initializes the CPU, AHB and APB busses clocks */ RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_HSI; RCC_OscInitStruct.HSIState = RCC_HSI_ON; RCC_OscInitStruct.HSICalibrationValue = RCC_HSICALIBRATION_DEFAULT; RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON; RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSI; RCC_OscInitStruct.PLL.PLLM = 8;//8 RCC_OscInitStruct.PLL.PLLN = 180; //180 RCC_OscInitStruct.PLL.PLLP = RCC_PLLP_DIV2; RCC_OscInitStruct.PLL.PLLQ = 2; RCC_OscInitStruct.PLL.PLLR = 2; if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK) { //Error_Handler(); } /** Activate the Over-Drive mode */ if (HAL_PWREx_EnableOverDrive() != HAL_OK) { //Error_Handler(); } /** Initializes the CPU, AHB and APB busses clocks */ RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_HCLK|RCC_CLOCKTYPE_SYSCLK |RCC_CLOCKTYPE_PCLK1|RCC_CLOCKTYPE_PCLK2; RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK; RCC_ClkInitStruct.AHBCLKDivider = RCC_SYSCLK_DIV1; RCC_ClkInitStruct.APB1CLKDivider = RCC_HCLK_DIV4; RCC_ClkInitStruct.APB2CLKDivider = RCC_HCLK_DIV2; if (HAL_RCC_ClockConfig(&RCC_ClkInitStruct, FLASH_LATENCY_5) != HAL_OK) { //Error_Handler(); } } float u_past[num_array_u_past] = {0.0f}; float x_past[num_array_x_past] = {0.0f}; float x_future[num_array_x_future] = {0.0f}; float f_past[num_array_f_past] = {0.0f}; float f_future[num_array_f_future] = {0.0f}; float input_NN[num_input] = { 0.0f }; const float h1[num_input][16] = { {-0.08928373456001282f,0.18988078832626343f,0.14029145240783691f,-0.11808817088603973f,-0.003978874068707228f,-0.007696872111409903f,0.42820632457733154f,-0.20236220955848694f,0.939854085445404f,-0.07558992505073547f,-0.027743147686123848f,-0.3279592990875244f,-0.31727975606918335f,-0.20024743676185608f,0.3523602783679962f,-0.6278733611106873f}, {-0.11774742603302002f,0.09604662656784058f,0.29011616110801697f,0.2234950214624405f,0.23440349102020264f,0.5232492089271545f,0.2210281491279602f,-0.3678447902202606f,0.7886034250259399f,-0.27516597509384155f,-0.2500557601451874f,-0.12492232769727707f,-0.11310917139053345f,-0.4406680464744568f,0.1511378139257431f,-0.4245671331882477f}, {0.36453908681869507f,-0.02021932601928711f,-0.3012392818927765f,-0.3477104902267456f,0.5035558342933655f,-0.3530597984790802f,-0.3702338933944702f,-0.3288705348968506f,0.3931751549243927f,0.23595577478408813f,-0.6494159698486328f,0.13738729059696198f,-0.0888165533542633f,0.3261997401714325f,0.1456020325422287f,-0.08090786635875702f}, {-0.4103831648826599f,-0.12864279747009277f,0.1022421345114708f,-0.6185715198516846f,-0.2637539505958557f,-0.328195184469223f,0.4355844259262085f,0.12046816200017929f,-0.13170522451400757f,-0.21010851860046387f,-0.34591883420944214f,0.23238110542297363f,-0.09013718366622925f,0.3507763743400574f,-0.12376902252435684f,-0.4103527069091797f}, {-0.4158014953136444f,0.4469558000564575f,-0.4252530634403229f,-0.7594079375267029f,0.15881256759166718f,0.570539653301239f,0.20091718435287476f,0.11978109925985336f,-0.6337155103683472f,-0.3290080726146698f,-0.538169264793396f,0.10523770749568939f,0.08139365911483765f,0.19170653820037842f,0.16857746243476868f,-0.6932903528213501f}, {0.02771398425102234f,-0.4239081144332886f,-0.1293027102947235f,-0.9767598509788513f,-0.005095937754958868f,0.12170109897851944f,-0.265327125787735f,-0.20950207114219666f,-1.7486470937728882f,-0.4134688079357147f,-0.32466891407966614f,-0.4746890366077423f,0.3993561267852783f,0.027073565870523453f,-0.4189585745334625f,-0.658713698387146f}, {0.4493045210838318f,-0.17244070768356323f,0.21882575750350952f,3.133983612060547f,-1.4239774942398071f,-0.9012263417243958f,0.39546728134155273f,-0.7601503133773804f,3.533515691757202f,-0.09566733241081238f,-0.49558505415916443f,0.12108597159385681f,-0.4244987964630127f,-0.3255382776260376f,0.1717403382062912f,0.15440697968006134f}, {0.234513521194458f,-0.16211813688278198f,0.33604222536087036f,2.0154271125793457f,-0.8926435708999634f,-0.2883564531803131f,0.17530131340026855f,-0.08909942954778671f,1.4232977628707886f,-0.0270843505859375f,-0.23662754893302917f,-0.039105724543333054f,-0.17777305841445923f,-0.2930698096752167f,-0.295630544424057f,0.8173853754997253f}, {0.35531145334243774f,0.32643234729766846f,-0.20846526324748993f,0.5044971108436584f,-0.6685876846313477f,0.013467200100421906f,-0.3044210970401764f,-0.61872798204422f,-0.29994454979896545f,-0.24198894202709198f,0.044176068156957626f,-0.2424609363079071f,-0.4050760865211487f,0.014094186946749687f,0.11948834359645844f,0.08273530006408691f}, {-0.15392860770225525f,0.3473075032234192f,-0.25585490465164185f,-0.34898388385772705f,-0.30887138843536377f,-0.27727174758911133f,-0.4218664765357971f,0.2524242699146271f,-0.9651307463645935f,-0.2347547560930252f,-0.2579735219478607f,0.13620002567768097f,-0.45715731382369995f,-0.2101370245218277f,-0.3693336844444275f,0.5827489495277405f}, {-0.434734970331192f,-0.1676338016986847f,-0.16730430722236633f,-0.7783320546150208f,-0.4176149368286133f,-0.0822678655385971f,-0.4028127193450928f,-0.15296562016010284f,-1.7470310926437378f,0.23425424098968506f,0.2960582673549652f,0.4209096133708954f,-0.02016448974609375f,-0.3919544517993927f,-0.18460549414157867f,-0.5643852949142456f}, {-0.2947876453399658f,-0.3233926296234131f,-0.396773099899292f,-1.4096735715866089f,-0.6982089877128601f,0.09473533183336258f,0.16410261392593384f,-0.2024194449186325f,-2.3709700107574463f,0.3230099678039551f,-0.33460134267807007f,0.14395946264266968f,0.41723358631134033f,-0.5597719550132751f,0.2465231865644455f,-0.376107782125473f}, }; const float h2[16][16] = { {0.22040846943855286f,-0.4028656780719757f,-0.30482804775238037f,0.2847701609134674f,0.37607017159461975f,-0.12173402309417725f,-0.27083414793014526f,0.19983914494514465f,0.12811920046806335f,0.026121854782104492f,0.33117517828941345f,0.31377163529396057f,-0.3039761185646057f,0.10410508513450623f,0.019344478845596313f,0.13114729523658752f}, {0.07885774970054626f,0.2685442268848419f,-0.20929814875125885f,-0.013690829277038574f,-0.28124189376831055f,0.3748907744884491f,-0.4218168258666992f,-0.13014042377471924f,0.34662631154060364f,0.2236320674419403f,-0.2787289619445801f,-0.16978111863136292f,-0.12639987468719482f,-0.11595618724822998f,0.20541444420814514f,-0.19707195460796356f}, {-0.289584755897522f,-0.3754548728466034f,0.4180505573749542f,-0.3319404125213623f,-0.12211531400680542f,0.40512141585350037f,-0.25835028290748596f,0.42814746499061584f,-0.3197705149650574f,0.35452306270599365f,0.20276597142219543f,-0.1963835507631302f,-0.26259419322013855f,0.10237613320350647f,-0.21197760105133057f,-0.054215338081121445f}, {-4.1213297843933105f,0.01764225959777832f,-0.27558714151382446f,-0.24608424305915833f,0.2943190336227417f,0.2841133773326874f,-0.35425087809562683f,0.02605552040040493f,0.25242629647254944f,-1.1704930067062378f,0.17697389423847198f,-0.26277410984039307f,-2.00290846824646f,0.10458657145500183f,0.19668230414390564f,0.3635267913341522f}, {-0.6215770244598389f,-0.22804522514343262f,-0.2246006429195404f,0.053406450897455215f,0.27491495013237f,-0.12348288297653198f,0.27004075050354004f,-0.147074893116951f,0.11645037680864334f,-0.15487730503082275f,-0.10510046780109406f,-0.2283875197172165f,0.13212068378925323f,-0.1956327110528946f,-0.09801927208900452f,0.11065234243869781f}, {0.10445184260606766f,-0.1510087102651596f,0.4312331974506378f,-0.5101251006126404f,0.2854827046394348f,0.34281787276268005f,-0.13838697969913483f,0.09894201159477234f,-0.23495729267597198f,0.08734504133462906f,-0.04059183597564697f,0.2733362019062042f,0.015527419745922089f,-0.10023930668830872f,-0.02278757095336914f,0.07353436946868896f}, {-0.22515183687210083f,-0.3755156993865967f,-0.24480870366096497f,-0.29299992322921753f,0.059763699769973755f,0.20225438475608826f,0.33751097321510315f,0.3263198435306549f,-0.13278412818908691f,-0.095187246799469f,-0.2782473564147949f,-0.3706819713115692f,-0.021951347589492798f,0.27562615275382996f,0.03849485516548157f,0.29575976729393005f}, {0.32057708501815796f,-0.524069607257843f,0.37138256430625916f,0.2010936439037323f,0.08615626394748688f,-0.03286612033843994f,0.15765780210494995f,-0.4324454665184021f,0.327019602060318f,-0.07884476333856583f,-0.1301749050617218f,-0.10347366333007812f,0.18177057802677155f,0.10729780793190002f,-0.10135778784751892f,-0.27579066157341003f}, {-1.386614441871643f,-0.49351364374160767f,-0.3842683434486389f,0.07866570353507996f,2.973254919052124f,-0.2822301983833313f,0.2986585795879364f,-0.17486296594142914f,-0.31111371517181396f,-0.29488277435302734f,-0.21365593373775482f,-0.36962851881980896f,-1.2022932767868042f,-0.29541951417922974f,-0.00033593177795410156f,2.188819646835327f}, {-0.15491563081741333f,-0.1982559859752655f,-0.27656543254852295f,-0.057386428117752075f,0.006925225257873535f,-0.0061952173709869385f,-0.30878782272338867f,-0.16744297742843628f,-0.15944159030914307f,-0.07186901569366455f,0.1433509886264801f,-0.11715862154960632f,0.009978801012039185f,-0.23373784124851227f,0.4134136140346527f,-0.22950156033039093f}, {0.06308726221323013f,-0.36588433384895325f,-0.08402159810066223f,0.028938988223671913f,-0.2953241169452667f,-0.28359758853912354f,0.345768541097641f,0.010517789050936699f,-0.3439469635486603f,-0.39201247692108154f,-0.22572417557239532f,0.17512741684913635f,0.13216380774974823f,0.23759087920188904f,-0.2779344618320465f,0.2651509642601013f}, {0.10504072904586792f,-0.03749573230743408f,0.33709099888801575f,0.37907975912094116f,0.22565968334674835f,0.3120448887348175f,0.39507538080215454f,0.006597965955734253f,-0.18118223547935486f,-0.42720532417297363f,-0.3804808259010315f,-0.25502610206604004f,0.0865727886557579f,0.4289310872554779f,0.1356206238269806f,-0.004186863079667091f}, {0.09193530678749084f,-0.18952275812625885f,0.0726877748966217f,0.3987469971179962f,0.02890300750732422f,-0.12990233302116394f,0.14810273051261902f,0.01665481925010681f,-0.15090349316596985f,-0.33036649227142334f,-0.003201425075531006f,-0.3811122179031372f,0.22158536314964294f,0.17805215716362f,0.1948237121105194f,-0.08180281519889832f}, {-0.06925216317176819f,-0.2162439227104187f,0.05184563994407654f,-0.01202910952270031f,0.03321986272931099f,-0.24826626479625702f,-0.5580893754959106f,0.30383768677711487f,-0.3802972733974457f,-0.40310049057006836f,0.13739612698554993f,-0.07380381226539612f,0.004031330347061157f,0.4251040518283844f,-0.12451288104057312f,-0.4890829622745514f}, {-0.13223494589328766f,-0.11442816257476807f,0.18836888670921326f,0.0025912465061992407f,-0.19410231709480286f,0.04468163847923279f,0.19008231163024902f,0.3492031395435333f,0.014439105987548828f,-0.16926728188991547f,0.05260401964187622f,-0.19738321006298065f,0.17389413714408875f,0.09360900521278381f,-0.18755027651786804f,-0.24380405247211456f}, {-0.6347722411155701f,-0.6213594675064087f,-0.28505873680114746f,-6.113732814788818f,-0.8829705119132996f,-0.39796411991119385f,-0.04346449673175812f,-0.11873544752597809f,-0.04968378692865372f,-1.9817637205123901f,-0.3773333430290222f,-0.2845912575721741f,-1.1904109716415405f,0.09081563353538513f,-0.27721232175827026f,0.04428445175290108f}, }; const float h3[16][16] = { {-0.3740372061729431f,-0.12622219324111938f,0.7481427788734436f,0.3189202547073364f,-2.452293872833252f,0.05530071258544922f,0.10995236039161682f,0.25306645035743713f,0.5455286502838135f,0.3019128143787384f,-0.3977643549442291f,1.2452392578125f,-0.08900150656700134f,0.2659699618816376f,-0.4051627218723297f,0.3587193489074707f}, {0.2580176293849945f,-0.21952059864997864f,-0.536188006401062f,-0.13161329925060272f,-0.3679931163787842f,0.21937689185142517f,0.19945386052131653f,-0.2553171217441559f,-0.009911770932376385f,0.06814399361610413f,-0.09381365776062012f,0.25755026936531067f,-0.326202392578125f,-0.40252116322517395f,0.0038833022117614746f,0.014371702447533607f}, {-0.06709745526313782f,-0.3487962782382965f,0.15876320004463196f,-0.08722096681594849f,-0.10967022180557251f,-0.4167609214782715f,0.1344209611415863f,-0.41463586688041687f,-0.37066638469696045f,-0.0406363308429718f,-0.17699375748634338f,-0.05360245704650879f,0.38655009865760803f,-0.01810634136199951f,-0.18493060767650604f,0.35194751620292664f}, {-0.12081655859947205f,-0.16580137610435486f,-0.43180301785469055f,2.575126886367798f,-1.9781299829483032f,-0.09152081608772278f,-0.3956339359283447f,-0.48883336782455444f,-0.22402389347553253f,0.7732234597206116f,-0.36379221081733704f,0.251196026802063f,-0.43051815032958984f,-0.3846364915370941f,-0.1842559427022934f,-0.7160226702690125f}, {0.005010038614273071f,-0.09848810732364655f,-1.4794831275939941f,-0.14799992740154266f,0.36386820673942566f,-0.42805469036102295f,-0.31440508365631104f,-0.0329747200012207f,1.4564002752304077f,-0.5649462342262268f,-1.146892786026001f,-1.6677275896072388f,-0.06857957690954208f,0.13153156638145447f,-0.2856975793838501f,-0.5936042666435242f}, {-0.154278963804245f,0.15068575739860535f,-0.23259520530700684f,0.3329792320728302f,0.16978946328163147f,0.07678303122520447f,0.11548694968223572f,0.25491419434547424f,-0.29460608959198f,-0.2147803008556366f,-0.09733334183692932f,0.0077544450759887695f,0.17424574494361877f,0.24004992842674255f,0.10598781704902649f,0.3885243237018585f}, {-0.06189775466918945f,-0.2343900054693222f,0.41815266013145447f,-0.06278818845748901f,0.038058292120695114f,0.05758383870124817f,-0.04267755150794983f,-0.28957313299179077f,-0.0036431453190743923f,-0.3373270332813263f,-0.4336230456829071f,0.05202546715736389f,0.1869029700756073f,0.09306725859642029f,-0.05534625053405762f,-0.23965637385845184f}, {0.11816993355751038f,0.19791188836097717f,0.045647695660591125f,0.05645141005516052f,-0.18168418109416962f,0.1770211160182953f,-0.2681187689304352f,-0.0303591787815094f,-0.1650286614894867f,-0.10919004678726196f,0.2986362874507904f,-0.07121747732162476f,-0.09518930315971375f,-0.35569754242897034f,0.42722514271736145f,-0.15241912007331848f}, {-0.08454379439353943f,-0.1466067135334015f,0.2962970435619354f,0.21947136521339417f,0.21353144943714142f,0.2355630099773407f,0.0014078617095947266f,0.0649329423904419f,-0.29372382164001465f,-0.2304542511701584f,-0.11185473203659058f,0.0468500554561615f,0.34780290722846985f,0.19274309277534485f,-0.311842143535614f,0.3789503276348114f}, {-0.09536594152450562f,0.3562287390232086f,0.8924842476844788f,0.4579148590564728f,0.7366642951965332f,0.3642789423465729f,0.4044777452945709f,-0.42047369480133057f,-0.019772857427597046f,-0.23059403896331787f,0.047575924545526505f,0.400556743144989f,0.17998197674751282f,0.3105376064777374f,-0.42501863837242126f,0.10465378314256668f}, {0.043095797300338745f,0.3075747787952423f,0.2890697419643402f,0.33099862933158875f,0.1751062572002411f,-0.3616466522216797f,0.2722831070423126f,-0.11669030785560608f,-0.02601027488708496f,-0.2050226330757141f,0.05298447608947754f,0.14272931218147278f,0.05636057257652283f,0.18077662587165833f,0.024709969758987427f,-0.2825847268104553f}, {0.114739328622818f,-0.28732842206954956f,-0.007510572671890259f,0.05885201692581177f,-0.17437449097633362f,0.26788774132728577f,0.31876376271247864f,0.30347469449043274f,-0.39352715015411377f,0.09197589755058289f,-0.27865278720855713f,-0.04290211200714111f,0.02039027214050293f,0.09758958220481873f,-0.38352450728416443f,0.35282430052757263f}, {-0.16227436065673828f,0.3044901192188263f,1.500205159187317f,-0.20669551193714142f,-0.8930017948150635f,0.3205467760562897f,-0.3996381461620331f,0.3226601779460907f,0.5433998107910156f,0.18693169951438904f,-0.6948516964912415f,0.9673228859901428f,-0.05647093057632446f,-0.12768149375915527f,0.15764620900154114f,0.7655152082443237f}, {-0.4156169295310974f,0.20866098999977112f,0.02854001522064209f,0.011706173419952393f,0.04473334550857544f,-0.338489294052124f,0.13951000571250916f,-0.1403215527534485f,-0.3943132162094116f,-0.16522809863090515f,-0.17043307423591614f,-0.42026638984680176f,-0.22834034264087677f,0.32368162274360657f,-0.22774425148963928f,0.33402350544929504f}, {0.2766123116016388f,-0.43157315254211426f,-0.2738536596298218f,0.16261598467826843f,-0.209463432431221f,0.11931833624839783f,0.151057630777359f,0.41193607449531555f,0.235458105802536f,0.16423484683036804f,-0.39183735847473145f,-0.06453084945678711f,-0.3313708007335663f,-0.27633973956108093f,0.270766943693161f,-0.05490243434906006f}, {-0.3373720347881317f,-0.3408786356449127f,-0.19662676751613617f,0.04992261901497841f,1.2588192224502563f,-0.19240692257881165f,0.05765652284026146f,0.07387390732765198f,-2.614326000213623f,0.7213937640190125f,-0.4090003967285156f,0.03824680298566818f,0.0996483862400055f,-0.061470746994018555f,-0.05823567509651184f,-0.10553636401891708f}, }; const float hout[16] = { 0.3696172833442688f,-0.033239372074604034f,1.0031309127807617f,1.0643973350524902f,-0.5450873374938965f,0.2716830372810364f,-0.2568954825401306f,0.13510213792324066f,2.1077351570129395f,0.6897874474525452f,0.06623781472444534f,1.021472692489624f,-0.16785483062267303f,-0.5563539266586304f,-0.3882039189338684f,0.5990738272666931f }; const float b1[16] = { -1.1430004835128784f,-1.1792505979537964f,0.137104794383049f,1.2572994232177734f,0.585432231426239f,-0.22034820914268494f,-0.9570482969284058f,0.7503839731216431f,1.030627965927124f,-2.6199684143066406f,0.6522615551948547f,-0.21148066222667694f,-1.5748937129974365f,-0.1155807301402092f,-0.2153463065624237f,2.533480644226074f }; const float b2[16] = { 0.24008359014987946f,-0.2304793894290924f,-0.9013299345970154f,0.8089731335639954f,-0.4296902120113373f,-0.8439559936523438f,-0.922905445098877f,-0.0648953840136528f,-1.008384346961975f,-0.048680439591407776f,-0.3683401644229889f,-1.3363648653030396f,-0.15714435279369354f,-0.8010820150375366f,-0.449018269777298f,-0.7082654237747192f }; const float b3[16] = { -0.3623056709766388f,-0.954131007194519f,-0.13478882610797882f,-0.7724200487136841f,0.2596184015274048f,-2.7422733306884766f,-0.741806149482727f,-1.2988611459732056f,-0.5918604731559753f,0.17699366807937622f,-0.037729937583208084f,-0.43741947412490845f,-0.9366039633750916f,-1.991359829902649f,-1.0550254583358765f,-0.35188284516334534f }; const float bout[1] = { 0.6205869317054749f }; float valve_ref_pos_buffer[10] = {0.0f}; /////////////////////////////////////////////////////////////////////////////////////////////RL float input_RL[num_input_RL] = { 0.0f }; //Critic Networks float hc1[num_input_RL][num_hidden_unit1] = {0.0f}; float bc1[num_hidden_unit1] = {0.0f}; float hc2[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float bc2[num_hidden_unit2] = {0.0f}; float hc3[num_hidden_unit2] = {0.0f}; float bc3 = 0.0f; //Critic Networks Temporary float hc1_temp[num_input_RL][num_hidden_unit1] = {0.0f}; float bc1_temp[num_hidden_unit1] = {0.0f}; float hc2_temp[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float bc2_temp[num_hidden_unit2] = {0.0f}; float hc3_temp[num_hidden_unit2] = {0.0f}; float bc3_temp = 0.0f; //Actor Networks float ha1[num_input_RL][num_hidden_unit1] = {0.0f}; float ba1[num_hidden_unit1] = {0.0f}; float ha2[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float ba2[num_hidden_unit2] = {0.0f}; float ha3[num_hidden_unit2][2] = {0.0f}; float ba3[2] = {0.0f}; //Actor Networks Temporary float ha1_temp[num_input_RL][num_hidden_unit1] = {0.0f}; float ba1_temp[num_hidden_unit1] = {0.0f}; float ha2_temp[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float ba2_temp[num_hidden_unit2] = {0.0f}; float ha3_temp[num_hidden_unit2][2] = {0.0f}; float ba3_temp[2] = {0.0f}; float VALVE_POS_RAW_NN = 0.0f; float DDV_JOINT_POS_FF(float REF_JOINT_VEL); /////////////////////////////////////////////RL tuning float Gradient_Limit = 0.5f; float gradient_rate_actor = 0.001f; float gradient_rate_critic = 0.001f; ////////////////////////////////////////////////////////////////////////////// float Critic_Network_Temp(float *arr) { float output1[num_hidden_unit1] = { 0.0f }; float output2[num_hidden_unit2] = { 0.0f }; float output = 0.0f; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { output1[index2] = output1[index2] + hc1_temp[index1][index2] * arr[index1]; } //ReLU output1[index2] = output1[index2] + bc1_temp[index2]; hx_c_sum[index2] = output1[index2]; if (output1[index2] < 0) { output1[index2] = 0; } //tanh //output1[index2] = tanh(output1[index2] + bc1_temp[index2]); } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { output2[index2] = output2[index2] + hc2_temp[index1][index2] * output1[index1]; } //ReLU output2[index2] = output2[index2] + bc2_temp[index2]; hxh_c_sum[index2] = output2[index2]; if (output2[index2] < 0) { output2[index2] = 0; } //tanh //output2[index2] = tanh(output2[index2] + bc2_temp[index2]); } for (int index2 = 0; index2 < 1; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { output = output + hc3_temp[index1] * output2[index1]; } output = output + bc3_temp; hxhh_c_sum = output; } return output; } void Actor_Network(float *arr) { float output1[num_hidden_unit1] = {0.0f}; float output2[num_hidden_unit2] = {0.0f}; float output[2] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { output1[index2] = output1[index2] + ha1_temp[index1][index2] * arr[index1]; } output1[index2] = output1[index2] + ba1_temp[index2]; hx_a_sum[index2] = output1[index2]; if (output1[index2] < 0) { output1[index2] = 0; } } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { output2[index2] = output2[index2] + ha2_temp[index1][index2] * output1[index1]; } output2[index2] = output2[index2] + ba2_temp[index2]; hxh_a_sum[index2] = output2[index2]; if (output2[index2] < 0) { output2[index2] = 0; } } for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { output[index2] = output[index2] + ha3_temp[index1][index2] * output2[index1]; } hxhh_a_sum[index2] = output[index2] + ba3_temp[index2]; } mean_before_SP = output[0] + ba3_temp[0]; //SP = softplus deviation_before_SP = output[1] + ba3_temp[1]; //Softplus mean = log(1.0f+exp(mean_before_SP)); deviation = log(1.0f+exp(deviation_before_SP)); logging2 = mean; logging4 = deviation; } void Actor_Network_Old(float *arr) { float output1[num_hidden_unit1] = {0.0f}; float output2[num_hidden_unit2] = {0.0f}; float output[2] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { output1[index2] = output1[index2] + ha1[index1][index2] * arr[index1]; } output1[index2] = output1[index2] + ba1[index2]; if (output1[index2] < 0) { output1[index2] = 0; } } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { output2[index2] = output2[index2] + ha2[index1][index2] * output1[index1]; } output2[index2] = output2[index2] + ba2[index2]; if (output2[index2] < 0) { output2[index2] = 0; } } for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { output[index2] = output[index2] + ha3[index1][index2] * output2[index1]; } } mean_old = output[0] + ba3[0]; deviation_old = output[1] + ba3[1]; //Softplus mean_old = log(1.0f+exp(mean_old)); deviation_old = log(1.0f+exp(deviation_old)); } float Grad_Normal_Dist_Mean(float mean, float deviation, float action) { float grad_mean = 0.0f; grad_mean = (action-mean)*exp(-(action-mean)*(action-mean)/(2.0f*deviation*deviation))/(sqrt(2.0f*PI)*deviation*deviation*deviation); return grad_mean; } float Grad_Normal_Dist_Deviation(float mean, float deviation, float action) { float grad_dev = 0.0f; grad_dev = exp(-(action-mean)*(action-mean)/(2.0f*deviation*deviation))*(-1.0f/(sqrt(2.0f*PI)*deviation*deviation) + (action-mean)*(action-mean)/(sqrt(2.0f*PI)*deviation*deviation*deviation*deviation)); return grad_dev; } float ReLU(float x) { if (x >= 0) { return x; } else { return 0.0f; } } void update_Critic_Networks(float (*arr)[num_input_RL]) { float G_hc1[num_input_RL][num_hidden_unit1] = {0.0f}; float G_bc1[num_hidden_unit1] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { for (int n=0; n<batch_size; n++) { float d_V_d_hc1 = 0.0f; for(int k=0; k<num_hidden_unit2; k++) { if (hxh_c_sum_array[n][k] >= 0) { if (hx_c_sum_array[n][index2] > 0) { d_V_d_hc1 = d_V_d_hc1 + arr[n][index1]*hc2_temp[index2][k]*hc3_temp[k]; } } } G_hc1[index1][index2] = G_hc1[index1][index2] + 2.0f*(return_G[n]-V[n])*(-d_V_d_hc1); } G_hc1[index1][index2] = G_hc1[index1][index2] / batch_size; if(G_hc1[index1][index2] > Gradient_Limit) G_hc1[index1][index2] = Gradient_Limit; else if (G_hc1[index1][index2] < -Gradient_Limit) G_hc1[index1][index2] = -Gradient_Limit; //hc1_temp[index1][index2] = hc1_temp[index1][index2] - gradient_rate_critic * G_hc1[index1][index2]; } for (int n=0; n<batch_size; n++) { float d_V_d_bc1 = 0.0f; for(int k=0; k<num_hidden_unit2; k++) { if (hxh_c_sum_array[n][k] >= 0) { if (hx_c_sum_array[n][index2] > 0) { d_V_d_bc1 = d_V_d_bc1 + hc2_temp[index2][k]*hc3_temp[k]; } } } G_bc1[index2] = G_bc1[index2] + 2.0f*(return_G[n]-V[n])*(-d_V_d_bc1); } G_bc1[index2] = G_bc1[index2] / batch_size; if(G_bc1[index2] > Gradient_Limit) G_bc1[index2] = Gradient_Limit; else if (G_bc1[index2] < -Gradient_Limit) G_bc1[index2] = -Gradient_Limit; //bc1_temp[index2] = bc1_temp[index2] - gradient_rate_critic * G_bc1[index2]; } float G_hc2[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float G_bc2[num_hidden_unit2] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { for (int n=0; n<batch_size; n++) { float d_V_d_hc2 = 0.0f; if (hxh_c_sum_array[n][index2] >= 0) { if (hx_c_sum_array[n][index1] > 0) { d_V_d_hc2 = hx_c_sum_array[n][index1]*hc3_temp[index2]; } } G_hc2[index1][index2] = G_hc2[index1][index2] + 2.0f*(return_G[n]-V[n])*(-d_V_d_hc2); } G_hc2[index1][index2] = G_hc2[index1][index2] / batch_size; if(G_hc2[index1][index2] > Gradient_Limit) G_hc2[index1][index2] = Gradient_Limit; else if (G_hc2[index1][index2] < -Gradient_Limit) G_hc2[index1][index2] = -Gradient_Limit; //hc2_temp[index1][index2] = hc2_temp[index1][index2] - gradient_rate_critic * G_hc2[index1][index2]; } for (int n=0; n<batch_size; n++) { float d_V_d_bc2 = 0.0f; if (hxh_c_sum_array[n][index2] >= 0) { d_V_d_bc2 = hc3_temp[index2]; } G_bc2[index2] = G_bc2[index2] + 2.0f*(return_G[n]-V[n])*(-d_V_d_bc2); } G_bc2[index2] = G_bc2[index2] / batch_size; if(G_bc2[index2] > Gradient_Limit) G_bc2[index2] = Gradient_Limit; else if (G_bc2[index2] < -Gradient_Limit) G_bc2[index2] = -Gradient_Limit; //bc2_temp[index2] = bc2_temp[index2] - gradient_rate_critic * G_bc2[index2]; } float G_hc3[num_hidden_unit2]= {0.0f}; float G_bc3 = 0.0f; for (int index2 = 0; index2 < 1; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { for (int n=0; n<batch_size; n++) { float d_V_d_hc3 = 0.0f; if (hxh_c_sum_array[n][index1] >= 0) { d_V_d_hc3 = d_V_d_hc3 + hxh_c_sum_array[n][index1]; } G_hc3[index1] = G_hc3[index1] + 2.0f*(return_G[n]-V[n])*(-d_V_d_hc3); } G_hc3[index1] = G_hc3[index1] / batch_size; if(G_hc3[index1] > Gradient_Limit) G_hc3[index1] = Gradient_Limit; else if (G_hc3[index1] < -Gradient_Limit) G_hc3[index1] = -Gradient_Limit; //hc3_temp[index1] = hc3_temp[index1] - gradient_rate_critic * G_hc3[index1]; } for (int n=0; n<batch_size; n++) { float d_V_d_bc3 = 0.0f; d_V_d_bc3 = 1.0f; G_bc3 = G_bc3 + 2.0f*(return_G[n]-V[n])*(-d_V_d_bc3); } G_bc3 = G_bc3 / batch_size; if(G_bc3 > Gradient_Limit) G_bc3 = Gradient_Limit; else if (G_bc3 < -Gradient_Limit) G_bc3 = -Gradient_Limit; //bc3_temp = bc3_temp - gradient_rate_critic * G_bc3; } // Simultaneous Update for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { hc1_temp[index1][index2] = hc1_temp[index1][index2] - gradient_rate_critic * G_hc1[index1][index2]; } bc1_temp[index2] = bc1_temp[index2] - gradient_rate_critic * G_bc1[index2]; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { hc2_temp[index1][index2] = hc2_temp[index1][index2] - gradient_rate_critic * G_hc2[index1][index2]; } bc2_temp[index2] = bc2_temp[index2] - gradient_rate_critic * G_bc2[index2]; } for (int index2 = 0; index2 < 1; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { hc3_temp[index1] = hc3_temp[index1] - gradient_rate_critic * G_hc3[index1]; } bc3_temp = bc3_temp - gradient_rate_critic * G_bc3; } } ///////////////////////////Softplus////////////////////////////////// void update_Actor_Networks(float (*arr)[num_input_RL]) { float G_ha1[num_input_RL][num_hidden_unit1] = {0.0f}; float G_ba1[num_hidden_unit1] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { for (int n=0; n<batch_size; n++) { float d_x_d_ha1 = 0.0f; float d_y_d_ha1 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ha1[index1][index2] = G_ha1[index1][index2]; } else { for(int k=0; k<num_hidden_unit2; k++) { if (hxh_a_sum_array[n][k] >= 0) { if (hx_a_sum_array[n][index2] > 0) { d_x_d_ha1 = d_x_d_ha1 + arr[n][index1]*ha2_temp[index2][k]*ha3_temp[k][0]; d_y_d_ha1 = d_y_d_ha1 + arr[n][index1]*ha2_temp[index2][k]*ha3_temp[k][1]; } } } float d_mean_d_ha1 = 0.0f; float d_dev_d_ha1 = 0.0f; d_mean_d_ha1 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ha1; d_dev_d_ha1 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ha1; G_ha1[index1][index2] = G_ha1[index1][index2] + advantage[n]/pi_old[n]*(d_mean_d_ha1*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ha1*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ha1[index1][index2] = -G_ha1[index1][index2] / batch_size; if(G_ha1[index1][index2] > Gradient_Limit) G_ha1[index1][index2] = Gradient_Limit; else if (G_ha1[index1][index2] < -Gradient_Limit) G_ha1[index1][index2] = -Gradient_Limit; //ha1_temp[index1][index2] = ha1_temp[index1][index2] - gradient_rate_actor * G_ha1[index1][index2]; } for (int n=0; n<batch_size; n++) { float d_x_d_ba1 = 0.0f; float d_y_d_ba1 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ba1[index2] = G_ba1[index2]; } else { for(int k=0; k<num_hidden_unit2; k++) { if (hxh_a_sum_array[n][k] >= 0) { if (hx_a_sum_array[n][index2] > 0) { d_x_d_ba1 = d_x_d_ba1 + ha2_temp[index2][k]*ha3_temp[k][0]; d_y_d_ba1 = d_y_d_ba1 + ha2_temp[index2][k]*ha3_temp[k][1]; } } } float d_mean_d_ba1 = 0.0f; float d_dev_d_ba1 = 0.0f; d_mean_d_ba1 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ba1; d_dev_d_ba1 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ba1; G_ba1[index2] = G_ba1[index2] + advantage[n]/pi_old[n]*(d_mean_d_ba1*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ba1*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ba1[index2] = -G_ba1[index2] / batch_size; if(G_ba1[index2] > Gradient_Limit) G_ba1[index2] = Gradient_Limit; else if (G_ba1[index2] < -Gradient_Limit) G_ba1[index2] = -Gradient_Limit; //ba1_temp[index2] = ba1_temp[index2] - gradient_rate_actor * G_ba1[index2]; } float G_ha2[num_hidden_unit1][num_hidden_unit2] = {0.0f}; float G_ba2[num_hidden_unit2] = {0.0f}; for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { for (int n=0; n<batch_size; n++) { float d_x_d_ha2 = 0.0f; float d_y_d_ha2 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ha2[index1][index2] = G_ha2[index1][index2]; } else { if (hxh_a_sum_array[n][index2] >= 0) { if (hx_a_sum_array[n][index1] > 0) { d_x_d_ha2 = hx_a_sum_array[n][index1]*ha3_temp[index2][0]; d_y_d_ha2 = hx_a_sum_array[n][index1]*ha3_temp[index2][1]; } } float d_mean_d_ha2 = 0.0f; float d_dev_d_ha2 = 0.0f; d_mean_d_ha2 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ha2; d_dev_d_ha2 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ha2; G_ha2[index1][index2] = G_ha2[index1][index2] + advantage[n]/pi_old[n]*(d_mean_d_ha2*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ha2*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ha2[index1][index2] = -G_ha2[index1][index2] / batch_size; if(G_ha2[index1][index2] > Gradient_Limit) G_ha2[index1][index2] = Gradient_Limit; else if (G_ha2[index1][index2] < -Gradient_Limit) G_ha2[index1][index2] = -Gradient_Limit; //ha2_temp[index1][index2] = ha2_temp[index1][index2] - gradient_rate_actor * G_ha2[index1][index2]; } for (int n=0; n<batch_size; n++) { float d_x_d_ba2 = 0.0f; float d_y_d_ba2 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ba2[index2] = G_ba2[index2]; } else { if (hxh_a_sum_array[n][index2] >= 0) { d_x_d_ba2 = ha3_temp[index2][0]; d_y_d_ba2 = ha3_temp[index2][1]; } float d_mean_d_ba2= 0.0f; float d_dev_d_ba2= 0.0f; d_mean_d_ba2 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ba2; d_dev_d_ba2 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ba2; G_ba2[index2] = G_ba2[index2] + advantage[n]/pi_old[n]*(d_mean_d_ba2*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ba2*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ba2[index2] = -G_ba2[index2] / batch_size; if(G_ba2[index2] > Gradient_Limit) G_ba2[index2] = Gradient_Limit; else if (G_ba2[index2] < -Gradient_Limit) G_ba2[index2] = -Gradient_Limit; //ba2_temp[index2] = ba2_temp[index2] - gradient_rate_actor * G_ba2[index2]; } float G_ha3[num_hidden_unit2][2] = {0.0f}; float G_ba3[2] = {0.0f}; for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { for (int n=0; n<batch_size; n++) { float d_x_d_ha3 = 0.0f; float d_y_d_ha3 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ha3[index1][index2] = G_ha3[index1][index2]; } else { if (hxh_a_sum_array[n][index1] >= 0) { if (hx_a_sum_array[n][index1] > 0) { d_x_d_ha3 = hxh_a_sum_array[n][index1]; d_y_d_ha3 = hxh_a_sum_array[n][index1]; } } float d_mean_d_ha3 = 0.0f; float d_dev_d_ha3 = 0.0f; d_mean_d_ha3 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ha3; d_dev_d_ha3 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ha3; G_ha3[index1][index2] = G_ha3[index1][index2] + advantage[n]/pi_old[n]*(d_mean_d_ha3*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ha3*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ha3[index1][index2] = -G_ha3[index1][index2] / batch_size; if(G_ha3[index1][index2] > Gradient_Limit) G_ha3[index1][index2] = Gradient_Limit; else if (G_ha3[index1][index2] < -Gradient_Limit) G_ha3[index1][index2] = -Gradient_Limit; //ha3_temp[index1][index2] = ha3_temp[index1][index2] - gradient_rate_actor * G_ha3[index1][index2]; } for (int n=0; n<batch_size; n++) { float d_x_d_ba3 = 0.0f; float d_y_d_ba3 = 0.0f; if((advantage[n] >= 0.0f && ratio[n] >= 1.0f + epsilon) || (advantage[n] < 0.0f && ratio[n] < 1.0f - epsilon)) { G_ba3[index2] = G_ba3[index2]; } else { d_x_d_ba3 = 1.0f; d_y_d_ba3 = 1.0f; float d_mean_d_ba3= 0.0f; float d_dev_d_ba3= 0.0f; d_mean_d_ba3 = exp(hxhh_a_sum_array[n][0])/(1.0f+exp(hxhh_a_sum_array[n][0]))*d_x_d_ba3; d_dev_d_ba3 = exp(hxhh_a_sum_array[n][1])/(1.0f+exp(hxhh_a_sum_array[n][1]))*d_y_d_ba3; G_ba3[index2] = G_ba3[index2] + advantage[n]/pi_old[n]*(d_mean_d_ba3*Grad_Normal_Dist_Mean(mean_array[n],deviation_array[n],action_array[n])+d_dev_d_ba3*Grad_Normal_Dist_Deviation(mean_array[n],deviation_array[n],action_array[n])); } } G_ba3[index2] = -G_ba3[index2] / batch_size; if(G_ba3[index2] > Gradient_Limit) G_ba3[index2] = Gradient_Limit; else if (G_ba3[index2] < -Gradient_Limit) G_ba3[index2] = -Gradient_Limit; //ba3_temp[index2] = ba3_temp[index2] - gradient_rate_actor * G_ba3[index2]; } // Simultaneous Update for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { ha1_temp[index1][index2] = ha1_temp[index1][index2] - gradient_rate_actor * G_ha1[index1][index2]; } ba1_temp[index2] = ba1_temp[index2] - gradient_rate_actor * G_ba1[index2]; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { ha2_temp[index1][index2] = ha2_temp[index1][index2] - gradient_rate_actor * G_ha2[index1][index2]; } ba2_temp[index2] = ba2_temp[index2] - gradient_rate_actor * G_ba2[index2]; } for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { ha3_temp[index1][index2] = ha3_temp[index1][index2] - gradient_rate_actor * G_ha3[index1][index2]; } ba3_temp[index2] = ba3_temp[index2] - gradient_rate_actor * G_ba3[index2]; } } float rand_normal(double mean, double stddev) { //Box muller method static double n2 = 0.0f; static int n2_cached = 0; if (!n2_cached) { double x, y, r; do { x = 2.0f*rand()/RAND_MAX - 1; y = 2.0f*rand()/RAND_MAX - 1; r = x*x + y*y; } while (r == 0.0f || r > 1.0f); { double d = sqrt(-2.0f*log(r)/r); double n1 = x*d; n2 = y*d; double result = n1*stddev + mean; n2_cached = 1; return result; } } else { n2_cached = 0; return n2*stddev + mean; } } float mean_adv(float x[], int size) { float add = 0.0f; float result; for (int i=0; i<size; i++) { add += x[i]; } result = (float) add/size; return result; } float deviation_adv(float x[], int size) { float sigma = 0.0f; float resultDeb = 0.0f; for (int k=0; k<size; k++) { sigma = pow((float)x[k]-mean_adv(x,size), (float)2.0f)/(size-1); resultDeb += sqrt(sigma); } return resultDeb; } void Overwirte_Critic_Networks() { for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { hc1[index1][index2] = hc1_temp[index1][index2]; } bc1[index2] = bc1_temp[index2]; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { hc2[index1][index2] = hc2_temp[index1][index2]; } bc2[index2] = bc2_temp[index2]; hc3[index2] = hc3_temp[index2]; } bc3 = bc3_temp; } void Overwirte_Actor_Networks() { for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { ha1[index1][index2] = ha1_temp[index1][index2]; } ba1[index2] = ba1_temp[index2]; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { ha2[index1][index2] = ha2_temp[index1][index2]; } ba2[index2] = ba2_temp[index2]; } for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { ha3[index1][index2] = ha3_temp[index1][index2]; } ba3[index2] = ba3_temp[index2]; } } int main() { HAL_Init(); SystemClock_Config(); /********************************* *** Initialization *********************************/ LED = 0; pc.baud(9600); // i2c init i2c.frequency(400 * 1000); // 0.4 mHz wait_ms(2); // Power Up wait look_for_hardware_i2c(); // Hardware present init_as5510(i2c_slave_addr1); make_delay(); // // spi init eeprom.format(8,3); eeprom.frequency(5000000); //5M enc.format(8,0); enc.frequency(5000000); //5M make_delay(); //rom ROM_CALL_DATA(); make_delay(); // ADC init Init_ADC(); make_delay(); // Pwm init Init_PWM(); TIM4->CR1 ^= TIM_CR1_UDIS; make_delay(); // TMR3 init Init_TMR3(); TIM3->CR1 ^= TIM_CR1_UDIS; make_delay(); // TMR2 init // Init_TMR2(); // TIM2->CR1 ^= TIM_CR1_UDIS; // make_delay(); // CAN can.attach(&CAN_RX_HANDLER); CAN_ID_INIT(); make_delay(); //Timer priority NVIC_SetPriority(TIM3_IRQn, 2); //NVIC_SetPriority(TIM2_IRQn, 3); NVIC_SetPriority(TIM4_IRQn, 3); //can.reset(); can.filter(msg.id, 0xFFFFF000, CANStandard); // spi _ enc spi_enc_set_init(); make_delay(); //DAC init if (SENSING_MODE == 0) { dac_1 = TORQUE_VREF / 3.3f; dac_2 = 0.0f; } else if (SENSING_MODE == 1) { dac_1 = PRES_A_VREF / 3.3f; dac_2 = PRES_B_VREF / 3.3f; } make_delay(); for (int i=0; i<50; i++) { if(i%2==0) ID_index_array[i] = - i * 0.5f; else ID_index_array[i] = (i+1) * 0.5f; } for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { hc1_temp[index1][index2] = (float) (rand()%100) * 0.007f ; } bc1_temp[index2] = (float) (rand()%100) * 0.007f; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { hc2_temp[index1][index2] = (float) (rand()%100) * 0.007f; } bc2_temp[index2] = (float) (rand()%100) * 0.007f; hc3_temp[index2] = (float) (rand()%100) * 0.007f; } bc3_temp = (float) (rand()%100) * 0.007f; for (int index2 = 0; index2 < num_hidden_unit1; index2++) { for (int index1 = 0; index1 < num_input_RL; index1++) { ha1_temp[index1][index2] = (float) (rand()%100) * 0.007f; } ba1_temp[index2] = (float) (rand()%100) * 0.007f; } for (int index2 = 0; index2 < num_hidden_unit2; index2++) { for (int index1 = 0; index1 < num_hidden_unit1; index1++) { ha2_temp[index1][index2] = (float) (rand()%100) * 0.007f; } ba2_temp[index2] = (float) (rand()%100) * 0.007f; } for (int index2 = 0; index2 < 2; index2++) { for (int index1 = 0; index1 < num_hidden_unit2; index1++) { ha3_temp[index1][index2] = (float) (rand()%100) * 0.007f; } ba3_temp[index2] = (float) (rand()%100) * 0.007f; } Overwirte_Critic_Networks(); Overwirte_Actor_Networks(); /************************************ *** Program is operating! *************************************/ while(1) { // if(timer_while==27491) { // timer_while = 0; // pc.printf("ref : %f virt_pos : %f mean : %f deviation : %f Last_pos_of_batch : %f reward_sum : %f\n", pos.sen/(float)(ENC_PULSE_PER_POSITION), logging3, logging2, logging4, logging1, logging5); // //pc.printf("%f\n", virt_pos); // //pc.printf("%f\n", pos.sen/(float)(ENC_PULSE_PER_POSITION)); // //pc.printf("ref : %f virt_pos : %f\n", pos.sen/(float)(ENC_PULSE_PER_POSITION), virt_pos); // } //i2c read_field(i2c_slave_addr1); if(DIR_VALVE_ENC < 0) value = 1023 - value; //timer_while ++; ///////////////////////////////////////////////////////Neural Network if(NN_Control_Flag == 0) { LED = 0; } else if(NN_Control_Flag == 1) { int ind = 0; for(int i=0; i<numpast_u; i++) { input_NN[ind] = u_past[time_interval*i]; ind = ind + 1; } for(int i=0; i<numpast_x; i++) { input_NN[ind] = x_past[time_interval*i] / 60.0f; ind = ind + 1; } input_NN[ind] = (pos.sen / ENC_PULSE_PER_POSITION) / 60.0f; ind = ind + 1; // for(int i=0; i<numfuture_x; i++) { // input_NN[ind] = x_future[time_interval*i+time_interval] / 60.0f; // ind = ind + 1; // } for(int i=0; i<numpast_f; i++) { // input_NN[ind] = f_past[time_interval*i] / 10000.0f * 8.0f + 0.5f; input_NN[ind] = f_past[time_interval*i] / 10000.0f + 0.5f; ind = ind + 1; } // input_NN[ind] = torq.sen / 10000.0f * 8.0f + 0.5f; input_NN[ind] = torq.sen / 10000.0f + 0.5f; ind = ind + 1; for(int i=0; i<numfuture_f; i++) { // input_NN[ind] = (f_future[time_interval*i+time_interval] - torq.sen)/10000.0f * 8.0f + 0.5f; // input_NN[ind] = (f_future[time_interval*i+time_interval] - torq.sen)/10000.0f + 0.5f; // input_NN[ind] = (f_future[time_interval*i+time_interval])/10000.0f*8.0f+0.5f; input_NN[ind] = (f_future[time_interval*i+time_interval])/10000.0f + 0.5f; ind = ind + 1; } float output1[16] = { 0.0f }; float output2[16] = { 0.0f }; float output3[16] = { 0.0f }; float output = 0.0f; for (int index2 = 0; index2 < 16; index2++) { for (int index1 = 0; index1 < num_input; index1++) { output1[index2] = output1[index2] + h1[index1][index2] * input_NN[index1]; } output1[index2] = output1[index2] + b1[index2]; if (output1[index2] < 0) { output1[index2] = 0; } } for (int index2 = 0; index2 < 16; index2++) { for (int index1 = 0; index1 < 16; index1++) { output2[index2] = output2[index2] + h2[index1][index2] * output1[index1]; } output2[index2] = output2[index2] + b2[index2]; if (output2[index2] < 0) { output2[index2] = 0; } } for (int index2 = 0; index2 < 16; index2++) { for (int index1 = 0; index1 < 16; index1++) { output3[index2] = output3[index2] + h3[index1][index2] * output2[index1]; } output3[index2] = output3[index2] + b3[index2]; if (output3[index2] < 0) { output3[index2] = 0; } } for (int index2 = 0; index2 < 1; index2++) { for (int index1 = 0; index1 < 16; index1++) { output = output + hout[index1] * output3[index1]; } output = output + bout[index2]; } output = 1.0f/(1.0f+exp(-output)); output_normalized = output; output = output * 20000.0f - 10000.0f; if(output>=0) { valve_pos.ref = output*0.0001f*((double)VALVE_MAX_POS - (double) VALVE_CENTER) + (double) VALVE_CENTER; } else { valve_pos.ref = -output*0.0001f*((double)VALVE_MIN_POS - (double) VALVE_CENTER) + (double) VALVE_CENTER; } if(LED==1) { LED=0; } else LED = 1; } /////////////////////////////////////////////////////////////////////RL switch (Update_Case) { case 0: { break; } case 1: { //Network Update(just update and hold network) for (int epoch = 0; epoch < num_epoch; epoch++) { float loss_sum = 0.0f; for (int n=batch_size-1; n>=0; n--) { //Calculate Estimated V //float temp_array[3] = {state_array[n][0], state_array[n][1], state_array[n][2]}; float temp_array[2] = {state_array[n][0], state_array[n][1]}; V[n] = Critic_Network_Temp(temp_array); for (int i=0; i<num_hidden_unit1; i++) { hx_c_sum_array[n][i] = hx_c_sum[i]; } for (int i=0; i<num_hidden_unit2; i++) { hxh_c_sum_array[n][i] = hxh_c_sum[i]; } hxhh_c_sum_array[n] = hxhh_c_sum; pi[n] = exp(-(action_array[n]-mean_array[n])*(action_array[n]-mean_array[n])/(2.0f*deviation_array[n]*deviation_array[n]))/(sqrt(2.0f*PI)*deviation_array[n]); Actor_Network_Old(temp_array); pi_old[n] = exp(-(action_array[n]-mean_old)*(action_array[n]-mean_old)/(2.0f*deviation_old*deviation_old))/(sqrt(2.0f*PI)*deviation_old); r[n] = exp(-0.25f * 5.0f * state_array[n][1] * state_array[n][1]); if(n == batch_size-1) return_G[n] = 0.0f; else return_G[n] = gamma * return_G[n+1] + r[n]; if(n == batch_size-1) td_target[n] = r[n]; else td_target[n] = r[n] + gamma * V[n+1]; delta[n] = td_target[n] - V[n]; if(n == batch_size-1) advantage[n] = 0.0f; else advantage[n] = gamma * lmbda * advantage[n+1] + delta[n]; // return_G[n] = advantage[n] + V[n]; ratio[n] = pi[n]/pi_old[n]; } float mean_advantage = 0.0f; float dev_advantage = 0.0f; mean_advantage = mean_adv(advantage, batch_size); dev_advantage = deviation_adv(advantage, batch_size); for (int n=batch_size-1; n>=0; n--) { //advantage[n] = (advantage[n]-mean_advantage)/dev_advantage; surr1[n] = ratio[n] * advantage[n]; if (ratio[n] > 1.0f + epsilon) { surr2[n] = (1.0f + epsilon)*advantage[n]; } else if( ratio[n] < 1.0f - epsilon) { surr2[n] = (1.0f - epsilon)*advantage[n]; } else { surr2[n] = ratio[n]*advantage[n]; } loss[n] = -min(surr1[n], surr2[n]); loss_sum = loss_sum + loss[n]; } reward_sum = 0.0f; for (int i=0; i<batch_size; i++) { reward_sum = reward_sum + r[i]; } logging5 = reward_sum; //loss_batch = loss_sum / (float) batch_size; loss_batch = loss_sum; //Update Networks update_Critic_Networks(state_array); update_Actor_Networks(state_array); } Update_Done_Flag = 1; Update_Case = 0; //logging1 = V[0]; break; } case 2: { //Network apply to next Network Overwirte_Critic_Networks(); Overwirte_Actor_Networks(); virt_pos = 10.0f; Update_Done_Flag = 1; Update_Case = 0; break; } } } } float DDV_JOINT_POS_FF(float REF_JOINT_VEL) { int i = 0; float Ref_Valve_Pos_FF = 0.0f; for(i=0; i<VALVE_POS_NUM; i++) { if(REF_JOINT_VEL >= min(JOINT_VEL[i],JOINT_VEL[i+1]) && REF_JOINT_VEL <= max(JOINT_VEL[i],JOINT_VEL[i+1])) { if(i==0) { if(JOINT_VEL[i+1] == JOINT_VEL[i]) { Ref_Valve_Pos_FF = (float) VALVE_CENTER; } else { Ref_Valve_Pos_FF = ((float) 10/(JOINT_VEL[i+1] - JOINT_VEL[i]) * (REF_JOINT_VEL - JOINT_VEL[i])) + (float) VALVE_CENTER; } } else { if(JOINT_VEL[i+1] == JOINT_VEL[i-1]) { Ref_Valve_Pos_FF = (float) VALVE_CENTER; } else { Ref_Valve_Pos_FF = ((float) 10*(ID_index_array[i+1] - ID_index_array[i-1])/(JOINT_VEL[i+1] - JOINT_VEL[i-1]) * (REF_JOINT_VEL - JOINT_VEL[i-1])) + (float) VALVE_CENTER + (float) (10*ID_index_array[i-1]); } } break; } } if(REF_JOINT_VEL > max(JOINT_VEL[VALVE_POS_NUM-1], JOINT_VEL[VALVE_POS_NUM-2])) { Ref_Valve_Pos_FF = (float) VALVE_MAX_POS; } else if(REF_JOINT_VEL < min(JOINT_VEL[VALVE_POS_NUM-1], JOINT_VEL[VALVE_POS_NUM-2])) { Ref_Valve_Pos_FF = (float) VALVE_MIN_POS; } Ref_Valve_Pos_FF = (float) VELOCITY_COMP_GAIN * 0.01f * (float) (Ref_Valve_Pos_FF - (float) VALVE_CENTER); return Ref_Valve_Pos_FF; } void VALVE_POS_CONTROL(float REF_VALVE_POS) { int i = 0; if(REF_VALVE_POS > VALVE_MAX_POS) { REF_VALVE_POS = VALVE_MAX_POS; } else if(REF_VALVE_POS < VALVE_MIN_POS) { REF_VALVE_POS = VALVE_MIN_POS; } valve_pos_err = (float) (REF_VALVE_POS - value); valve_pos_err_diff = valve_pos_err - valve_pos_err_old; valve_pos_err_old = valve_pos_err; valve_pos_err_sum += valve_pos_err; if (valve_pos_err_sum > 1000.0f) valve_pos_err_sum = 1000.0f; if (valve_pos_err_sum<-1000.0f) valve_pos_err_sum = -1000.0f; VALVE_PWM_RAW_FB = P_GAIN_VALVE_POSITION * valve_pos_err + I_GAIN_VALVE_POSITION * valve_pos_err_sum + D_GAIN_VALVE_POSITION * valve_pos_err_diff; for(i=0; i<24; i++) { if(REF_VALVE_POS >= min(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1]) && (float) REF_VALVE_POS <= max(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1])) { if(i==0) { VALVE_PWM_RAW_FF = (float) 1000.0f / (float) (VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i]); } else { VALVE_PWM_RAW_FF = (float) 1000.0f* (float) (ID_index_array[i+1] - ID_index_array[i-1])/(VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i-1]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i-1]) + 1000.0f * (float) ID_index_array[i-1]; } break; } } Vout.ref = VALVE_PWM_RAW_FF + VALVE_PWM_RAW_FB; } #define LT_MAX_IDX 57 float LT_PWM_duty[LT_MAX_IDX] = {-100.0f, -80.0f, -60.0f, -50.0f, -40.0f, -35.0f, -30.0f, -25.0f, -20.0f, -19.0f, -18.0f, -17.0f, -16.0f, -15.0f, -14.0f, -13.0f, -12.0f, -11.0f, -10.0f, -9.0f, -8.0f, -7.0f, -6.0f, -5.0f, -4.0f, -3.0f, -2.0f, -1.0f, 0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f, 10.0f, 11.0f, 12.0f, 13.0f, 14.0f, 15.0f, 16.0f, 17.0f, 18.0f, 19.0f, 20.0f, 25.0f, 30.0f, 35.0f, 40.0f, 50.0f, 60.0f, 80.0f, 100.0f }; // duty float LT_Voltage_Output[LT_MAX_IDX] = {-230.0f, -215.0f, -192.5f, -185.0f, -177.5f, -170.0f, -164.0f, -160.0f, -150.0f, -150.0f, -145.0f, -145.0f, -145.0f, -135.0f, -135.0f, -135.0f, -127.5f, -127.5f, -115.0f, -115.0f, -115.0F, -100.0f, -100.0f, -100.0f, -60.0f, -60.0f, -10.0f, -5.0f, 0.0f, 7.5f, 14.0f, 14.0f, 14.0f, 42.5f, 42.5f, 42.5f, 80.0f, 80.0f, 105.0f, 105.0f, 105.0f, 120.0f, 120.0f, 120.0f, 131.0f, 131.0f, 140.0f, 140.0f, 140.0f, 155.0f, 160.0f, 170.0f, 174.0f, 182.0f, 191.0f, 212.0f, 230.0f }; // mV float PWM_duty_byLT(float Ref_V) { float PWM_duty = 0.0f; if(Ref_V<LT_Voltage_Output[0]) { PWM_duty = (Ref_V-LT_Voltage_Output[0])/1.5f+LT_PWM_duty[0]; } else if (Ref_V>=LT_Voltage_Output[LT_MAX_IDX-1]) { PWM_duty = (Ref_V-LT_Voltage_Output[LT_MAX_IDX-1])/1.5f+LT_PWM_duty[LT_MAX_IDX-1]; } else { int idx = 0; for(idx=0; idx<LT_MAX_IDX-1; idx++) { float ini_x = LT_Voltage_Output[idx]; float fin_x = LT_Voltage_Output[idx+1]; float ini_y = LT_PWM_duty[idx]; float fin_y = LT_PWM_duty[idx+1]; if(Ref_V>=ini_x && Ref_V<fin_x) { PWM_duty = (fin_y-ini_y)/(fin_x-ini_x)*(Ref_V-ini_x) + ini_y; break; } } } return PWM_duty; } /******************************************************************************* TIMER INTERRUPT *******************************************************************************/ float FREQ_TMR4 = (float)FREQ_20k; float DT_TMR4 = (float)DT_20k; long CNT_TMR4 = 0; int TMR4_FREQ_10k = (int)FREQ_10k; extern "C" void TIM4_IRQHandler(void) { if (TIM4->SR & TIM_SR_UIF ) { /******************************************************* *** Sensor Read & Data Handling ********************************************************/ //Encoder if (CNT_TMR4 % (int) ((int) FREQ_TMR4/TMR4_FREQ_10k) == 0) { ENC_UPDATE(); } ADC1->CR2 |= 0x40000000; if (SENSING_MODE == 0) { // Torque Sensing (0~210)bar ============================================= float pres_A_new = (((float) ADC1->DR) - 2047.5f); double alpha_update_ft = 1.0f / (1.0f + FREQ_TMR4 / (2.0f * 3.14f * 100.0f)); // f_cutoff : 200Hz pres_A.sen = (1.0f - alpha_update_ft) * pres_A.sen + alpha_update_ft * pres_A_new; torq.sen = -pres_A.sen / TORQUE_SENSOR_PULSE_PER_TORQUE; // float alpha_update_pres_A = 1.0f/(1.0f + FREQ_TMR4/(2.0f*3.14f*100.0f)); //// float pres_A_new = ((float)ADC1->DR - PRES_A_NULL) / PRES_SENSOR_A_PULSE_PER_BAR; // float pres_A_new = ((float)ADC1->DR); // pres_A.sen = pres_A.sen*(1.0f-alpha_update_pres_A)+pres_A_new*(alpha_update_pres_A); // torq.sen = - (pres_A.sen-2048.0f); //pulse -2047~2047 } else if (SENSING_MODE == 1) { // Pressure Sensing (0~210)bar ============================================= float pres_A_new = (((float)ADC1->DR) - PRES_A_NULL); float pres_B_new = (((float)ADC2->DR) - PRES_B_NULL); double alpha_update_pres = 1.0f / (1.0f + FREQ_TMR4 / (2.0f * 3.14f * 200.0f)); // f_cutoff : 500Hz pres_A.sen = (1.0f - alpha_update_pres) * pres_A.sen + alpha_update_pres * pres_A_new; pres_B.sen = (1.0f - alpha_update_pres) * pres_B.sen + alpha_update_pres * pres_B_new; CUR_PRES_A_BAR = pres_A.sen / PRES_SENSOR_A_PULSE_PER_BAR; CUR_PRES_B_BAR = pres_B.sen / PRES_SENSOR_B_PULSE_PER_BAR; if ((OPERATING_MODE & 0x01) == 0) { // Rotary Actuator torq.sen = (PISTON_AREA_A * CUR_PRES_A_BAR - PISTON_AREA_B * CUR_PRES_B_BAR) * 0.0001f; // mm^3*bar >> Nm } else if ((OPERATING_MODE & 0x01) == 1) { // Linear Actuator torq.sen = (PISTON_AREA_A * CUR_PRES_A_BAR - PISTON_AREA_B * CUR_PRES_B_BAR) * 0.1f; // mm^2*bar >> N } } // //Pressure sensor A // ADC1->CR2 |= 0x40000000; // adc _ 12bit // //while((ADC1->SR & 0b10)); // float alpha_update_pres_A = 1.0f/(1.0f + FREQ_TMR4/(2.0f*3.14f*100.0f)); // float pres_A_new = ((float)ADC1->DR); // pres_A.sen = pres_A.sen*(1.0f-alpha_update_pres_A)+pres_A_new*(alpha_update_pres_A); // torq.sen = - (pres_A.sen-2048.0f); //pulse -2047~2047 //SW just changed the sign to correct the direction of loadcell on LIGHT. Correct later. // // // //Pressure sensor B // float alpha_update_pres_B = 1.0f/(1.0f + FREQ_TMR4/(2.0f*3.14f*100.0f)); // float pres_B_new = ((float)ADC2->DR); // pres_B.sen = pres_B.sen*(1.0f-alpha_update_pres_B)+pres_B_new*(alpha_update_pres_B); // //torq.sen = pres_A.sen * (float) PISTON_AREA_A - pres_B.sen * (float) PISTON_AREA_B; //Current //ADC3->CR2 |= 0x40000000; // adc _ 12bit //int raw_cur = ADC3->DR; //while((ADC3->SR & 0b10)); float alpha_update_cur = 1.0f/(1.0f + FREQ_TMR4/(2.0f*3.14f*500.0f)); // f_cutoff : 500Hz float cur_new = ((float)ADC3->DR-2048.0f)*20.0f/4096.0f; // unit : mA cur.sen=cur.sen*(1.0f-alpha_update_cur)+cur_new*(alpha_update_cur); //cur.sen = raw_cur; CNT_TMR4++; } TIM4->SR = 0x0; // reset the status register } int j =0; float FREQ_TMR3 = (float)FREQ_5k; float DT_TMR3 = (float)DT_5k; int cnt_trans = 0; double VALVE_POS_RAW_FORCE_FB_LOGGING = 0.0f; extern "C" void TIM3_IRQHandler(void) { if (TIM3->SR & TIM_SR_UIF ) { if (((OPERATING_MODE&0b110)>>1) == 0) { K_v = 0.4f; // Moog (LPM >> mA) , 100bar mV_PER_mA = 500.0f; // 5000mV/10mA mV_PER_pulse = 0.5f; // 5000mV/10000pulse mA_PER_pulse = 0.001f; // 10mA/10000pulse } else if (((OPERATING_MODE&0b110)>>1) == 1) { K_v = 0.5f; // KNR (LPM >> mA) , 100bar mV_PER_mA = 166.6666f; // 5000mV/30mA mV_PER_pulse = 0.5f; // 5000mV/10000pulse mA_PER_pulse = 0.003f; // 30mA/10000pulse } if(MODE_POS_FT_TRANS == 1) { alpha_trans = (float)(1.0f - cos(3.141592f * (float)cnt_trans * DT_TMR3 /3.0f))/2.0f; cnt_trans++; torq.err_sum = 0; if((float)cnt_trans * DT_TMR3 > 3.0f) MODE_POS_FT_TRANS = 2; } else if(MODE_POS_FT_TRANS == 3) { alpha_trans = (float)(1.0f + cos(3.141592f * (float)cnt_trans * DT_TMR3 /3.0f))/2.0f; cnt_trans++; torq.err_sum = 0; if((float) cnt_trans * DT_TMR3 > 3.0f ) MODE_POS_FT_TRANS = 0; } else if(MODE_POS_FT_TRANS == 2) { alpha_trans = 1.0f; cnt_trans = 0; } else { alpha_trans = 0.0f; cnt_trans = 0; } int UTILITY_MODE = 0; int CONTROL_MODE = 0; if (CONTROL_UTILITY_MODE >= 20 || CONTROL_UTILITY_MODE == 0) { UTILITY_MODE = CONTROL_UTILITY_MODE; CONTROL_MODE = MODE_NO_ACT; } else { CONTROL_MODE = CONTROL_UTILITY_MODE; UTILITY_MODE = MODE_NO_ACT; } // UTILITY MODE ------------------------------------------------------------ switch (UTILITY_MODE) { case MODE_NO_ACT: { break; } case MODE_TORQUE_SENSOR_NULLING: { // DAC Voltage reference set if (TMR3_COUNT_TORQUE_NULL < TMR_FREQ_5k * 2) { CUR_TORQUE_sum += torq.sen; if (TMR3_COUNT_TORQUE_NULL % 10 == 0) { CUR_TORQUE_mean = CUR_TORQUE_sum / 10.0f; CUR_TORQUE_sum = 0; TORQUE_VREF += 0.000003f * (0.0f - CUR_TORQUE_mean); if (TORQUE_VREF > 3.3f) TORQUE_VREF = 3.3f; if (TORQUE_VREF < 0.0f) TORQUE_VREF = 0.0f; //spi_eeprom_write(RID_TORQUE_SENSOR_VREF, (int16_t) (TORQUE_VREF * 1000.0)); dac_1 = TORQUE_VREF / 3.3f; } } else { CONTROL_UTILITY_MODE = MODE_NO_ACT; TMR3_COUNT_TORQUE_NULL = 0; CUR_TORQUE_sum = 0; CUR_TORQUE_mean = 0; // ROM_RESET_DATA(); spi_eeprom_write(RID_TORQUE_SENSOR_VREF, (int16_t) (TORQUE_VREF * 1000.0f)); dac_1 = TORQUE_VREF / 3.3f; } TMR3_COUNT_TORQUE_NULL++; break; } // case MODE_VALVE_NULLING_AND_DEADZONE_SETTING: { // if (TMR3_COUNT_DEADZONE == 0) { // if (pos_plus_end == pos_minus_end) need_enc_init = true; // else temp_time = 0; // } // if (need_enc_init) { // if (TMR3_COUNT_DEADZONE < (int) (0.5f * (float) TMR_FREQ_5k)) { // V_out = VALVE_VOLTAGE_LIMIT * 1000.0f; // pos_plus_end = pos.sen; // } else if (TMR3_COUNT_DEADZONE < TMR_FREQ_5k) { // V_out = -VALVE_VOLTAGE_LIMIT * 1000.0f; // pos_minus_end = pos.sen; // } else if (TMR3_COUNT_DEADZONE == TMR_FREQ_5k) need_enc_init = false; // temp_time = TMR_FREQ_5k; // } // // if (temp_time <= TMR3_COUNT_DEADZONE && TMR3_COUNT_DEADZONE < (temp_time + TMR_FREQ_5k)) { // V_out = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen); // VALVE_CENTER = VALVE_DEADZONE_PLUS = VALVE_DEADZONE_MINUS = 0; // // } else if (temp_time <= TMR3_COUNT_DEADZONE && TMR3_COUNT_DEADZONE < (temp_time + (int) (1.9f * (float) TMR_FREQ_5k))) { // V_out = 0; // CUR_VELOCITY_sum += CUR_VELOCITY; // } else if (TMR3_COUNT_DEADZONE == (temp_time + 2 * TMR_FREQ_5k)) { // if (CUR_VELOCITY_sum == 0) DZ_dir = 1; // else if (CUR_VELOCITY_sum > 0) DZ_dir = 1; // else if (CUR_VELOCITY_sum < 0) DZ_dir = -1; // else DZ_temp_cnt2 = DZ_end; // CUR_VELOCITY_sum = 0; // } else if (TMR3_COUNT_DEADZONE > (temp_time + 2 * TMR_FREQ_5k)) { // if (TMR3_COUNT_DEADZONE > (temp_time + 10 * TMR_FREQ_5k)) DZ_temp_cnt2 = DZ_end; // // // Position of Dead Zone // // (CUR_VELOCITY < 0) (CUR_VELOCITY == 0) (CUR_VELOCITY > 0) // // | / | / |/ // // | ______/ ___|___/ ______/| // // |/ / | / | // // /| / | / | // // 0V 0V 0V // // if (DZ_temp_cnt2 < DZ_end) { // if (TMR3_COUNT_DEADZONE % 20 != 0) { // CUR_VELOCITY_sum += CUR_VELOCITY; // } else { // V_out -= DZ_dir; // if (CUR_VELOCITY_sum * DZ_dir < 0) DZ_temp_cnt++; // CUR_VELOCITY_sum = 0; // } // if (DZ_temp_cnt == 5) { // if (DZ_dir >= 0) VALVE_DEADZONE_MINUS = (int16_t) V_out; // else VALVE_DEADZONE_PLUS = (int16_t) V_out; // DZ_dir = -DZ_dir; // DZ_temp_cnt = 0; // DZ_temp_cnt2++; // } // } else { // TMR3_COUNT_DEADZONE = -1; // VALVE_CENTER = VALVE_DEADZONE_PLUS / 2 + VALVE_DEADZONE_MINUS / 2; // if (VALVE_DEADZONE_PLUS < VALVE_DEADZONE_MINUS) { // VALVE_DEADZONE_PLUS = VALVE_CENTER; // VALVE_DEADZONE_MINUS = VALVE_CENTER; // } // V_out = 0; // // ROM_RESET_DATA(); // // //spi_eeprom_write(RID_VALVE_DEADZONE_PLUS, VALVE_DEADZONE_PLUS); // //spi_eeprom_write(RID_VALVE_DEADZONE_MINUS, VALVE_DEADZONE_MINUS); // // CONTROL_MODE = MODE_NO_ACT; // DZ_temp_cnt2 = 0; // } // } // TMR3_COUNT_DEADZONE++; // break; // } case MODE_FIND_HOME: { if (FINDHOME_STAGE == FINDHOME_INIT) { cnt_findhome = 0; cnt_vel_findhome = 0; //REFERENCE_MODE = MODE_REF_NO_ACT; // Stop taking reference data from PODO pos.ref = pos.sen; vel.ref = 0.0f; FINDHOME_STAGE = FINDHOME_GOTOLIMIT; } else if (FINDHOME_STAGE == FINDHOME_GOTOLIMIT) { int cnt_check_enc = (TMR_FREQ_5k/20); if(cnt_findhome%cnt_check_enc == 0) { FINDHOME_POSITION = pos.sen; FINDHOME_VELOCITY = FINDHOME_POSITION - FINDHOME_POSITION_OLD; FINDHOME_POSITION_OLD = FINDHOME_POSITION; } cnt_findhome++; if (abs(FINDHOME_VELOCITY) <= 1) { cnt_vel_findhome = cnt_vel_findhome + 1; } else { cnt_vel_findhome = 0; } if ((cnt_vel_findhome < 3*TMR_FREQ_5k) && cnt_findhome < 10*TMR_FREQ_5k) { // wait for 3sec //REFERENCE_MODE = MODE_REF_NO_ACT; if (HOMEPOS_OFFSET > 0) pos.ref = pos.ref + 12.0f; else pos.ref = pos.ref - 12.0f; // pos.err = pos.ref_home_pos - pos.sen; // float VALVE_POS_RAW_POS_FB = 0.0f; // VALVE_POS_RAW_POS_FB = (float) P_GAIN_JOINT_POSITION * pos.err/(float) ENC_PULSE_PER_POSITION * 0.01f; // valve_pos.ref = VALVE_POS_RAW_POS_FB + (float) VALVE_CENTER; // VALVE_POS_CONTROL(valve_pos.ref); CONTROL_MODE = MODE_JOINT_CONTROL; alpha_trans = 0.0f; } else { ENC_SET(HOMEPOS_OFFSET); // ENC_SET_ZERO(); INIT_REF_POS = HOMEPOS_OFFSET; REF_POSITION = 0; REF_VELOCITY = 0; FINDHOME_POSITION = 0; FINDHOME_POSITION_OLD = 0; FINDHOME_VELOCITY = 0; cnt_findhome = 0; cnt_vel_findhome = 0; FINDHOME_STAGE = FINDHOME_ZEROPOSE; cnt_findhome = 0; pos.ref = 0.0f; vel.ref = 0.0f; pos.ref_home_pos = 0.0f; vel.ref_home_pos = 0.0f; //FINDHOME_STAGE = FINDHOME_INIT; //CONTROL_UTILITY_MODE = MODE_JOINT_CONTROL; } } else if (FINDHOME_STAGE == FINDHOME_ZEROPOSE) { int T_move = 2*TMR_FREQ_5k; pos.ref = (0.0f - (float)INIT_REF_POS)*0.5f*(1.0f - cos(3.14159f * (float)cnt_findhome / (float)T_move)) + (float)INIT_REF_POS; //pos.ref = 0.0f; vel.ref = 0.0f; // input for position control // CONTROL_MODE = MODE_JOINT_CONTROL; alpha_trans = 0.0f; double torq_ref = 0.0f; pos.err = (pos.ref - pos.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm] vel.err = (0.0f - vel.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm/s] pos.err_sum += pos.err/(float) TMR_FREQ_5k; //[mm] if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { double I_REF_POS = 0.0f; double I_REF_FORCE_FB = 0.0f; // I_REF by Force Feedback double I_REF_VC = 0.0f; // I_REF for velocity compensation double temp_vel_pos = 0.0f; double temp_vel_torq = 0.0f; double wn_Pos = 2.0f * PI * 5.0f; // f_cut : 5Hz Position Control if ((OPERATING_MODE & 0x01) == 0) { // Rotary Mode temp_vel_pos = (0.01f * (double) P_GAIN_JOINT_POSITION * wn_Pos * pos.err + 0.01f * (double) I_GAIN_JOINT_POSITION * wn_Pos * pos.err_sum + 0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / ENC_PULSE_PER_POSITION) * 3.14159f / 180.0f; // rad/s // L when P-gain = 100, f_cut = 10Hz L feedforward velocity } else if ((OPERATING_MODE & 0x01) == 1) { temp_vel_pos = (0.01f * (double) P_GAIN_JOINT_POSITION * wn_Pos * pos.err + 0.01f * (double) I_GAIN_JOINT_POSITION * wn_Pos * pos.err_sum + 0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / ENC_PULSE_PER_POSITION); // mm/s // L when P-gain = 100, f_cut = 10Hz L feedforward velocity } if (temp_vel_pos > 0.0f) I_REF_POS = temp_vel_pos * ((double) PISTON_AREA_A * 0.00006f / (K_v * sqrt(2.0f * alpha3 / (alpha3 + 1.0f)))); else I_REF_POS = temp_vel_pos * ((double) PISTON_AREA_B * 0.00006f / (K_v * sqrt(2.0f / (alpha3 + 1.0f)))); I_REF = I_REF_POS; } else { float VALVE_POS_RAW_FORCE_FB = 0.0f; VALVE_POS_RAW_FORCE_FB = DDV_JOINT_POS_FF(vel.sen) + (P_GAIN_JOINT_POSITION * 0.01f * pos.err + DDV_JOINT_POS_FF(vel.ref)); if (VALVE_POS_RAW_FORCE_FB >= 0) { valve_pos.ref = VALVE_POS_RAW_FORCE_FB + VALVE_DEADZONE_PLUS; } else { valve_pos.ref = VALVE_POS_RAW_FORCE_FB + VALVE_DEADZONE_MINUS; } VALVE_POS_CONTROL(valve_pos.ref); V_out = (float) Vout.ref; } // pos.err = pos.ref - (float)pos.sen; // float VALVE_POS_RAW_POS_FB = 0.0f; // VALVE_POS_RAW_POS_FB = (float) P_GAIN_JOINT_POSITION * 0.01f * pos.err/(float) ENC_PULSE_PER_POSITION; // valve_pos.ref = VALVE_POS_RAW_POS_FB + (float) VALVE_CENTER; // VALVE_POS_CONTROL(valve_pos.ref); cnt_findhome++; if (cnt_findhome >= T_move) { //REFERENCE_MODE = MODE_REF_DIRECT; cnt_findhome = 0; pos.ref = 0.0f; vel.ref = 0.0f; pos.ref_home_pos = 0.0f; vel.ref_home_pos = 0.0f; FINDHOME_STAGE = FINDHOME_INIT; CONTROL_UTILITY_MODE = MODE_JOINT_CONTROL; } } break; } // case MODE_VALVE_GAIN_SETTING: { // if (TMR3_COUNT_FLOWRATE == 0) { // if (pos_plus_end == pos_minus_end) need_enc_init = true; // else { // V_out = -VALVE_VOLTAGE_LIMIT * 1000.0f; // temp_time = (int) (0.5f * (float) TMR_FREQ_5k); // } // } // if (need_enc_init) { // if (TMR3_COUNT_FLOWRATE < (int) (0.5f * (float) TMR_FREQ_5k)) { // V_out = VALVE_VOLTAGE_LIMIT * 1000.0f; // pos_plus_end = pos.sen; // } else if (TMR3_COUNT_FLOWRATE < TMR_FREQ_5k) { // V_out = -VALVE_VOLTAGE_LIMIT * 1000.0f; // pos_minus_end = pos.sen; // } else if (TMR3_COUNT_FLOWRATE == TMR_FREQ_5k) { // need_enc_init = false; // check_vel_pos_init = (int) (0.9f * (float) (pos_plus_end - pos_minus_end)); // check_vel_pos_fin = (int) (0.95f * (float) (pos_plus_end - pos_minus_end)); // check_vel_pos_interv = check_vel_pos_fin - check_vel_pos_init; // } // temp_time = TMR_FREQ_5k; // } // TMR3_COUNT_FLOWRATE++; // if (TMR3_COUNT_FLOWRATE > temp_time) { // if (flag_flowrate % 2 == 0) { // (+) // VALVE_VOLTAGE = 1000.0f * (float) (flag_flowrate / 2 + 1); // V_out = VALVE_VOLTAGE; // if (pos.sen > (pos_minus_end + check_vel_pos_init) && pos.sen < (pos_minus_end + check_vel_pos_fin)) { // fl_temp_cnt++; // } else if (pos.sen >= (pos_minus_end + check_vel_pos_fin) && CUR_VELOCITY == 0) { // VALVE_GAIN_LPM_PER_V[flag_flowrate] = 0.95873f * 0.5757f * (float) TMR_FREQ_5k / 10000.0 * (float) check_vel_pos_interv / (float) fl_temp_cnt / VALVE_VOLTAGE; // 0.9587=6*pi/65536*10000 0.5757=0.02525*0.02*0.0095*2*60*1000 // // VALVE_GAIN_LPM_PER_V[flag_flowrate] = (float) TMR_FREQ_10k * (float) check_vel_pos_interv / (float) fl_temp_cnt / VALVE_VOLTAGE; // PULSE/sec // fl_temp_cnt2++; // } // } else if (flag_flowrate % 2 == 1) { // (-) // VALVE_VOLTAGE = -1. * (float) (flag_flowrate / 2 + 1); // V_out = VALVE_VOLTAGE; // if (pos.sen < (pos_plus_end - check_vel_pos_init) && pos.sen > (pos_plus_end - check_vel_pos_fin)) { // fl_temp_cnt++; // } else if (pos.sen <= (pos_plus_end - check_vel_pos_fin) && CUR_VELOCITY == 0) { // VALVE_GAIN_LPM_PER_V[flag_flowrate] = 0.95873f * 0.5757f * (float) TMR_FREQ_5k / 10000.0f * (float) check_vel_pos_interv / (float) fl_temp_cnt / (-VALVE_VOLTAGE); // // VALVE_GAIN_LPM_PER_V[flag_flowrate] = (float) TMR_FREQ_10k * (float) check_vel_pos_interv / (float) fl_temp_cnt / (-VALVE_VOLTAGE); // PULSE/sec // fl_temp_cnt2++; // } // } // if (fl_temp_cnt2 == 100) { // // ROM_RESET_DATA(); // // //spi_eeprom_write(RID_VALVE_GAIN_PLUS_1 + flag_flowrate, (int16_t) (VALVE_GAIN_LPM_PER_V[flag_flowrate] * 100.0f)); // cur_vel_sum = 0; // fl_temp_cnt = 0; // fl_temp_cnt2 = 0; // flag_flowrate++; // } // if (flag_flowrate == 10) { // V_out = 0; // flag_flowrate = 0; // TMR3_COUNT_FLOWRATE = 0; // valve_gain_repeat_cnt++; // if (valve_gain_repeat_cnt >= 1) { // CONTROL_MODE = MODE_NO_ACT; // valve_gain_repeat_cnt = 0; // } // // } // break; // } // // } case MODE_PRESSURE_SENSOR_NULLING: { // DAC Voltage reference set if (TMR3_COUNT_PRES_NULL < TMR_FREQ_5k * 2) { CUR_PRES_A_sum += pres_A.sen; CUR_PRES_B_sum += pres_B.sen; if (TMR3_COUNT_PRES_NULL % 10 == 0) { CUR_PRES_A_mean = CUR_PRES_A_sum / 10.0f; CUR_PRES_B_mean = CUR_PRES_B_sum / 10.0f; CUR_PRES_A_sum = 0; CUR_PRES_B_sum = 0; float VREF_NullingGain = 0.0003f; PRES_A_VREF = PRES_A_VREF + VREF_NullingGain * CUR_PRES_A_mean; PRES_B_VREF = PRES_B_VREF + VREF_NullingGain * CUR_PRES_B_mean; if (PRES_A_VREF > 3.3f) PRES_A_VREF = 3.3f; if (PRES_A_VREF < 0.0f) PRES_A_VREF = 0.0f; if (PRES_B_VREF > 3.3f) PRES_B_VREF = 3.3f; if (PRES_B_VREF < 0.0f) PRES_B_VREF = 0.0f; dac_1 = PRES_A_VREF / 3.3f; dac_2 = PRES_B_VREF / 3.3f; } } else { CONTROL_UTILITY_MODE = MODE_NO_ACT; TMR3_COUNT_PRES_NULL = 0; CUR_PRES_A_sum = 0; CUR_PRES_B_sum = 0; CUR_PRES_A_mean = 0; CUR_PRES_B_mean = 0; // ROM_RESET_DATA(); spi_eeprom_write(RID_PRES_A_SENSOR_VREF, (int16_t) (PRES_A_VREF * 1000.0f)); spi_eeprom_write(RID_PRES_B_SENSOR_VREF, (int16_t) (PRES_B_VREF * 1000.0f)); dac_1 = PRES_A_VREF / 3.3f; dac_2 = PRES_B_VREF / 3.3f; //pc.printf("nulling end"); } TMR3_COUNT_PRES_NULL++; break; } // case MODE_PRESSURE_SENSOR_CALIB: { // if (TMR3_COUNT_PRES_CALIB < 2 * TMR_FREQ_5k) { // V_out = -VALVE_VOLTAGE_LIMIT * 1000.0f; // if (TMR3_COUNT_PRES_CALIB >= TMR_FREQ_5k) { // CUR_PRES_A_sum += CUR_PRES_A; // } // } else if (TMR3_COUNT_PRES_CALIB < 4 * TMR_FREQ_5k) { // V_out = VALVE_VOLTAGE_LIMIT * 1000.0f; // if (TMR3_COUNT_PRES_CALIB >= 3 * TMR_FREQ_5k) { // CUR_PRES_B_sum += CUR_PRES_B; // } // } else { // CONTROL_MODE = MODE_NO_ACT; // TMR3_COUNT_PRES_CALIB = 0; // V_out = 0; // PRES_SENSOR_A_PULSE_PER_BAR = CUR_PRES_A_sum / ((float) TMR_FREQ_5k - 1.0f) - PRES_A_NULL; // PRES_SENSOR_A_PULSE_PER_BAR = PRES_SENSOR_A_PULSE_PER_BAR / ((float) PRES_SUPPLY - 1.0f); // PRES_SENSOR_B_PULSE_PER_BAR = CUR_PRES_B_sum / ((float) TMR_FREQ_5k - 1.0f) - PRES_B_NULL; // PRES_SENSOR_B_PULSE_PER_BAR = PRES_SENSOR_B_PULSE_PER_BAR / ((float) PRES_SUPPLY - 1.0f); // CUR_PRES_A_sum = 0; // CUR_PRES_B_sum = 0; // CUR_PRES_A_mean = 0; // CUR_PRES_B_mean = 0; // // ROM_RESET_DATA(); // // //spi_eeprom_write(RID_PRES_SENSOR_A_PULSE_PER_BAR, (int16_t) (PRES_SENSOR_A_PULSE_PER_BAR * 100.0f)); // //spi_eeprom_write(RID_PRES_SENSOR_B_PULSE_PER_BAR, (int16_t) (PRES_SENSOR_B_PULSE_PER_BAR * 100.0f)); // } // TMR3_COUNT_PRES_CALIB++; // break; // } // case MODE_ROTARY_FRICTION_TUNING: { // if (TMR3_COUNT_ROTARY_FRIC_TUNE % (5 * TMR_FREQ_5k) == 0) freq_fric_tune = 4.0f + 3.0f * sin(2 * 3.14159f * 0.5f * TMR3_COUNT_ROTARY_FRIC_TUNE * 0.0001f * 0.05f); // V_out = PWM_out * sin(2 * 3.14159f * freq_fric_tune * TMR3_COUNT_ROTARY_FRIC_TUNE * 0.0001f); // if (V_out > 0) V_out = VALVE_VOLTAGE_LIMIT * 1000.0f; // else V_out = -VALVE_VOLTAGE_LIMIT * 1000.0f; // TMR3_COUNT_ROTARY_FRIC_TUNE++; // if (TMR3_COUNT_ROTARY_FRIC_TUNE > TUNING_TIME * TMR_FREQ_5k) { // TMR3_COUNT_ROTARY_FRIC_TUNE = 0; // V_out = 0.0f; // CONTROL_MODE = MODE_NO_ACT; // } // break; // } case MODE_DDV_POS_VS_PWM_ID: { CONTROL_MODE = MODE_VALVE_OPEN_LOOP; VALVE_ID_timer = VALVE_ID_timer + 1; if(VALVE_ID_timer < TMR_FREQ_5k*1) { Vout.ref = 3000.0f * sin(2.0f*3.14f*VALVE_ID_timer/TMR_FREQ_5k * 100.0f); } else if(VALVE_ID_timer < TMR_FREQ_5k*2) { Vout.ref = 1000.0f*(ID_index_array[ID_index]); } else if(VALVE_ID_timer == TMR_FREQ_5k*2) { VALVE_POS_TMP = 0; data_num = 0; } else if(VALVE_ID_timer < TMR_FREQ_5k*3) { data_num = data_num + 1; VALVE_POS_TMP = VALVE_POS_TMP + value; } else if(VALVE_ID_timer == TMR_FREQ_5k*3) { Vout.ref = 0.0f; } else { VALVE_POS_AVG[ID_index] = VALVE_POS_TMP / data_num; VALVE_ID_timer = 0; ID_index= ID_index +1; } if(ID_index>=25) { int i; VALVE_POS_AVG_OLD = VALVE_POS_AVG[0]; for(i=0; i<25; i++) { VALVE_POS_VS_PWM[i] = (int16_t) (VALVE_POS_AVG[i]); if(VALVE_POS_AVG[i] > VALVE_POS_AVG_OLD) { VALVE_MAX_POS = VALVE_POS_AVG[i]; VALVE_POS_AVG_OLD = VALVE_MAX_POS; } else if(VALVE_POS_AVG[i] < VALVE_POS_AVG_OLD) { VALVE_MIN_POS = VALVE_POS_AVG[i]; VALVE_POS_AVG_OLD = VALVE_MIN_POS; } } // ROM_RESET_DATA(); spi_eeprom_write(RID_VALVE_MAX_POS, (int16_t) VALVE_MAX_POS); spi_eeprom_write(RID_VALVE_MIN_POS, (int16_t) VALVE_MIN_POS); for(int i=0; i<25; i++) { spi_eeprom_write(RID_VALVE_POS_VS_PWM_0 + i, (int16_t) VALVE_POS_VS_PWM[i]); } ID_index = 0; CONTROL_UTILITY_MODE = MODE_NO_ACT; } break; } case MODE_DDV_DEADZONE_AND_CENTER: { CONTROL_MODE = MODE_VALVE_OPEN_LOOP; VALVE_DZ_timer = VALVE_DZ_timer + 1; if(first_check == 0) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; pos_plus_end = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; pos_minus_end = pos.sen; } else if(VALVE_DZ_timer < (int) (3.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; } else if(VALVE_DZ_timer < (int) (4.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; data_num = data_num + 1; VALVE_POS_TMP = VALVE_POS_TMP + value; } else if(VALVE_DZ_timer == (int) (4.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; DDV_POS_AVG = VALVE_POS_TMP / data_num; START_POS = pos.sen; VALVE_POS_TMP = 0; data_num = 0; } else if(VALVE_DZ_timer < (int) (5.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer < (int) (6.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer == (int) (6.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos.ref); FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>200) { DZ_case = 1; } else if((FINAL_POS - START_POS)<-200) { DZ_case = -1; } else { DZ_case = 0; } CAN_TX_PRES((int16_t) (DZ_case), (int16_t) (6)); first_check = 1; DZ_DIRECTION = 1; VALVE_DZ_timer = 0; Ref_Valve_Pos_Old = DDV_POS_AVG; DZ_NUM = 1; DZ_index = 1; } } else { if((DZ_case == -1 && DZ_NUM == 1) | (DZ_case == 1 && DZ_NUM == 1)) { if(VALVE_DZ_timer < (int) (1.0 * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; //pos.ref = 0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end; //CONTROL_MODE = MODE_JOINT_CONTROL; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 64 / DZ_index; if(valve_pos.ref <= VALVE_MIN_POS) { valve_pos.ref = VALVE_MIN_POS; } else if(valve_pos.ref >= VALVE_MAX_POS) { valve_pos.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>100) { DZ_DIRECTION = 1 * DZ_case; } else if((FINAL_POS - START_POS)<-100) { DZ_DIRECTION = -1 * DZ_case; } else { DZ_DIRECTION = 1 * DZ_case; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; if(DZ_index >= 128) { FIRST_DZ = valve_pos.ref; DZ_NUM = 2; Ref_Valve_Pos_Old = FIRST_DZ; DZ_index = 1; DZ_DIRECTION = 1; } } } else if((DZ_case == -1 && DZ_NUM == 2) | (DZ_case == 1 && DZ_NUM == 2)) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; //pos.ref = 0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end; //CONTROL_MODE = MODE_JOINT_CONTROL; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 64 / DZ_index; if(valve_pos.ref <= VALVE_MIN_POS) { valve_pos.ref = VALVE_MIN_POS; } else if(valve_pos.ref >= VALVE_MAX_POS) { valve_pos.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = 0.0f; } else if(VALVE_DZ_timer > (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>100) { DZ_DIRECTION = 1 * DZ_case; } else if((FINAL_POS - START_POS)<-100) { DZ_DIRECTION = -1 * DZ_case; } else { DZ_DIRECTION = -1 * DZ_case; } VALVE_DZ_timer = 0; DZ_index= DZ_index * 2; if(DZ_index >= 128) { SECOND_DZ = valve_pos.ref; VALVE_CENTER = (int) (0.5f * (float) (FIRST_DZ) + 0.5f * (float) (SECOND_DZ)); first_check = 0; VALVE_DEADZONE_MINUS = (float) FIRST_DZ; VALVE_DEADZONE_PLUS = (float) SECOND_DZ; // ROM_RESET_DATA(); spi_eeprom_write(RID_VALVE_CNETER, (int16_t) VALVE_CENTER); spi_eeprom_write(RID_VALVE_MAX_POS, (int16_t) VALVE_MAX_POS); spi_eeprom_write(RID_VALVE_MIN_POS, (int16_t) VALVE_MIN_POS); CONTROL_UTILITY_MODE = MODE_NO_ACT; DZ_index = 1; } } } else if(DZ_case == 0 && DZ_NUM ==1) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; //pos.ref = 0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end; //CONTROL_MODE = MODE_JOINT_CONTROL; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = Ref_Valve_Pos_Old - DZ_DIRECTION * 64 / DZ_index; if(valve_pos.ref <= VALVE_MIN_POS) { valve_pos.ref = VALVE_MIN_POS; } else if(valve_pos.ref >= VALVE_MAX_POS) { valve_pos.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>100) { DZ_DIRECTION = 1; } else if((FINAL_POS - START_POS)<-100) { DZ_DIRECTION = -1; } else { DZ_DIRECTION = 1; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; if(DZ_index >= 128) { FIRST_DZ = valve_pos.ref; DZ_NUM = 2; Ref_Valve_Pos_Old = FIRST_DZ; DZ_index = 1; DZ_DIRECTION = 1; } } } else { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; //pos.ref = 0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end; //CONTROL_MODE = MODE_JOINT_CONTROL; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = Ref_Valve_Pos_Old + DZ_DIRECTION * 64 / DZ_index; if(valve_pos.ref <= VALVE_MIN_POS) { valve_pos.ref = VALVE_MIN_POS; } else if(valve_pos.ref > VALVE_MAX_POS) { valve_pos.ref = VALVE_MAX_POS - 1; } VALVE_POS_CONTROL(valve_pos.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = 0.0f; } else if(VALVE_DZ_timer > (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>100) { DZ_DIRECTION = 1; } else if((FINAL_POS - START_POS)<-100) { DZ_DIRECTION = -1; } else { DZ_DIRECTION = 1; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; if(DZ_index >= 128) { SECOND_DZ = valve_pos.ref; VALVE_CENTER = (int) (0.5f * (float) (FIRST_DZ) + 0.5f * (float) (SECOND_DZ)); first_check = 0; VALVE_DEADZONE_MINUS = (float) FIRST_DZ; VALVE_DEADZONE_PLUS = (float) SECOND_DZ; // ROM_RESET_DATA(); spi_eeprom_write(RID_VALVE_CNETER, (int16_t) VALVE_CENTER); spi_eeprom_write(RID_VALVE_MAX_POS, (int16_t) VALVE_MAX_POS); spi_eeprom_write(RID_VALVE_MIN_POS, (int16_t) VALVE_MIN_POS); CONTROL_UTILITY_MODE = MODE_NO_ACT; DZ_index = 1; } } } } break; } case MODE_DDV_POS_VS_FLOWRATE: { CONTROL_MODE = MODE_VALVE_OPEN_LOOP; VALVE_FR_timer = VALVE_FR_timer + 1; if(first_check == 0) { if(VALVE_FR_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; //CAN_TX_PRES((int16_t) (VALVE_FR_timer), (int16_t) (6)); } else if(VALVE_FR_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; pos_plus_end = pos.sen; // CAN_TX_PRES((int16_t) (V_out), (int16_t) (7)); } else if(VALVE_FR_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; } else if(VALVE_FR_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { // CAN_TX_PRES((int16_t) (V_out), (int16_t) (8)); Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; pos_minus_end = pos.sen; first_check = 1; VALVE_FR_timer = 0; valve_pos.ref = (float) VALVE_CENTER; ID_index = 0; max_check = 0; min_check = 0; } } else { if(VALVE_FR_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { //V_out = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)/(float) ENC_PULSE_PER_POSITION; pos.ref = 0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end; CONTROL_MODE = MODE_JOINT_CONTROL; } else if(VALVE_FR_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { data_num = 0; valve_pos.ref = 10.0f*((float) ID_index_array[ID_index]) + (float) VALVE_CENTER; VALVE_POS_CONTROL(valve_pos.ref); START_POS = pos.sen; } else if(VALVE_FR_timer < (int) (5.0f * (float) TMR_FREQ_5k)) { valve_pos.ref = 10.0f*((float) ID_index_array[ID_index]) + (float) VALVE_CENTER; VALVE_POS_CONTROL(valve_pos.ref); data_num = data_num + 1; if(abs(0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen) > 20000.0f) { FINAL_POS = pos.sen; one_period_end = 1; } } else if(VALVE_FR_timer == (int) (5.0f * (float) TMR_FREQ_5k)) { FINAL_POS = pos.sen; one_period_end = 1; V_out = 0.0f; } if(one_period_end == 1) { if(valve_pos.ref > VALVE_MAX_POS) { max_check = 1; } else if(valve_pos.ref < VALVE_MIN_POS) { min_check = 1; } JOINT_VEL[ID_index] = (FINAL_POS - START_POS) / data_num * TMR_FREQ_5k; // pulse/sec VALVE_FR_timer = 0; one_period_end = 0; ID_index= ID_index +1; V_out = 0.0f; } if(max_check == 1 && min_check == 1) { VALVE_POS_NUM = ID_index; // ROM_RESET_DATA(); for(int i=0; i<100; i++) { spi_eeprom_write(RID_VALVE_POS_VS_FLOWRATE_0 + i, (int16_t) (JOINT_VEL[i] & 0xFFFF)); spi_eeprom_write(RID_VALVE_POS_VS_FLOWRATE_0_1 + i, (int16_t) ((JOINT_VEL[i] >> 16) & 0xFFFF)); } ID_index = 0; first_check = 0; VALVE_FR_timer = 0; CONTROL_UTILITY_MODE = MODE_NO_ACT; // CAN_TX_PRES((int16_t) (VALVE_FR_timer), (int16_t) (6)); } } break; } case MODE_SYSTEM_ID: { freq_sysid_Iref = (double) cnt_sysid * DT_TMR3 * 3.0f; valve_pos.ref = 2500.0f * sin(2.0f * 3.14159f * freq_sysid_Iref * (double) cnt_sysid * DT_TMR3); CONTROL_MODE = MODE_VALVE_OPEN_LOOP; cnt_sysid++; if (freq_sysid_Iref >= 300) { cnt_sysid = 0; CONTROL_UTILITY_MODE = MODE_NO_ACT; } break; } case MODE_FREQ_TEST: { float valve_pos_ref = 2500.0f * sin(2.0f * 3.141592f * freq_test_valve_ref * (float) cnt_freq_test * DT_TMR3); if(valve_pos_ref >= 0) { valve_pos.ref = (double)VALVE_CENTER + (double)valve_pos_ref * ((double)VALVE_MAX_POS-(double)VALVE_CENTER)/10000.0f; } else { valve_pos.ref = (double)VALVE_CENTER - (double)valve_pos_ref * ((double)VALVE_MIN_POS-(double)VALVE_CENTER)/10000.0f; } ref_array[cnt_freq_test] = valve_pos_ref; if(value>=(float) VALVE_CENTER) { pos_array[cnt_freq_test] = 10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MAX_POS - (double)VALVE_CENTER); } else { pos_array[cnt_freq_test] = -10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MIN_POS - (double)VALVE_CENTER); } CONTROL_MODE = MODE_VALVE_POSITION_CONTROL; cnt_freq_test++; if (freq_test_valve_ref * (float) cnt_freq_test * DT_TMR3 > 2) { buffer_data_size = cnt_freq_test; cnt_freq_test = 0; cnt_send_buffer = 0; freq_test_valve_ref = freq_test_valve_ref * 1.05f; if (freq_test_valve_ref >= 400) { CONTROL_UTILITY_MODE = MODE_NO_ACT; CONTROL_MODE = MODE_NO_ACT; CAN_TX_PWM((int16_t) (1)); //1300 } CONTROL_MODE = MODE_NO_ACT; CONTROL_UTILITY_MODE = MODE_SEND_OVER; } break; } case MODE_SEND_BUFFER: { // if (TMR2_COUNT_CAN_TX % (int) ((int) TMR_FREQ_5k/CAN_FREQ) == 0) { // CAN_TX_PRES((int16_t) (pos_array[cnt_send_buffer]), (int16_t) (ref_array[cnt_send_buffer])); // 1400 // if(cnt_send_buffer>=buffer_data_size) { // CONTROL_UTILITY_MODE = MODE_FREQ_TEST; // } // cnt_send_buffer++; // } break; } case MODE_SEND_OVER: { CAN_TX_TORQUE((int16_t) (buffer_data_size)); //1300 CONTROL_UTILITY_MODE = MODE_NO_ACT; CONTROL_MODE = MODE_NO_ACT; break; } case MODE_STEP_TEST: { float valve_pos_ref = 0.0f; if (cnt_step_test < (int) (1.0f * (float) TMR_FREQ_5k)) { valve_pos_ref = 0.0f; } else { valve_pos_ref = 10000.0f; } if(valve_pos_ref >= 0) { valve_pos.ref = (double)VALVE_CENTER + (double)valve_pos_ref * ((double)VALVE_MAX_POS-(double)VALVE_CENTER)/10000.0f; } else { valve_pos.ref = (double)VALVE_CENTER - (double)valve_pos_ref * ((double)VALVE_MIN_POS-(double)VALVE_CENTER)/10000.0f; } ref_array[cnt_step_test] = valve_pos_ref; if(value>=(float) VALVE_CENTER) { pos_array[cnt_step_test] = 10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MAX_POS - (double)VALVE_CENTER); } else { pos_array[cnt_step_test] = -10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MIN_POS - (double)VALVE_CENTER); } CONTROL_MODE = MODE_VALVE_POSITION_CONTROL; cnt_step_test++; if (cnt_step_test > (int) (2.0f * (float) TMR_FREQ_5k)) { buffer_data_size = cnt_step_test; cnt_step_test = 0; cnt_send_buffer = 0; CONTROL_UTILITY_MODE = MODE_SEND_OVER; CONTROL_MODE = MODE_NO_ACT; } // if (cnt_step_test > (int) (2.0f * (float) TMR_FREQ_5k)) // { // CONTROL_UTILITY_MODE = MODE_NO_ACT; // CONTROL_MODE = MODE_NO_ACT; // CAN_TX_PWM((int16_t) (1)); //1300 // } break; } default: break; } // CONTROL MODE ------------------------------------------------------------ switch (CONTROL_MODE) { case MODE_NO_ACT: { V_out = 0.0f; break; } case MODE_VALVE_POSITION_CONTROL: { if (OPERATING_MODE == 5) { //SW Valve ////For Test LIMC////////////////////////////////////////// VALVE_POS_CONTROL(valve_pos.ref); // for(int i=0; i<9; i++){ // valve_ref_pos_buffer[i] = valve_ref_pos_buffer[i+1]; // } // valve_ref_pos_buffer[9] = valve_pos.ref; // VALVE_POS_CONTROL(valve_ref_pos_buffer[0]); //////////////////////////////////////////////////////////// V_out = Vout.ref; } else if (CURRENT_CONTROL_MODE == 0) { //PWM V_out = valve_pos.ref; } else { I_REF = valve_pos.ref * 0.001f; } break; } case MODE_JOINT_CONTROL: { double torq_ref = 0.0f; pos.err = (pos.ref - pos.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm] vel.err = (0.0f - vel.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm/s] pos.err_sum += pos.err/(float) TMR_FREQ_5k; //[mm] //K & D Low Pass Filter float alpha_K_D = 1.0f/(1.0f + 5000.0f/(2.0f*3.14f*30.0f)); // f_cutoff : 30Hz K_LPF = K_LPF*(1.0f-alpha_K_D)+K_SPRING*(alpha_K_D); D_LPF = D_LPF*(1.0f-alpha_K_D)+D_DAMPER*(alpha_K_D); // torq_ref = torq.ref + K_LPF * pos.err - D_LPF * vel.sen / ENC_PULSE_PER_POSITION; //[N] torq_ref = torq.ref; // torque feedback torq.err = torq_ref - torq.sen; //[N] torq.err_sum += torq.err/(float) TMR_FREQ_5k; //[N] if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { double I_REF_POS = 0.0f; double I_REF_FORCE_FB = 0.0f; // I_REF by Force Feedback double I_REF_VC = 0.0f; // I_REF for velocity compensation double temp_vel_pos = 0.0f; double temp_vel_torq = 0.0f; double wn_Pos = 2.0f * PI * 5.0f; // f_cut : 5Hz Position Control if ((OPERATING_MODE & 0x01) == 0) { // Rotary Mode temp_vel_pos = (0.01f * (double) P_GAIN_JOINT_POSITION * wn_Pos * pos.err + 0.01f * (double) I_GAIN_JOINT_POSITION * wn_Pos * pos.err_sum + 0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / ENC_PULSE_PER_POSITION) * PI / 180.0f; // rad/s // L when P-gain = 100, f_cut = 10Hz L feedforward velocity } else if ((OPERATING_MODE & 0x01) == 1) { temp_vel_pos = (0.01f * (double) P_GAIN_JOINT_POSITION * wn_Pos * pos.err + 0.01f * (double) I_GAIN_JOINT_POSITION * wn_Pos * pos.err_sum + 0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / ENC_PULSE_PER_POSITION); // mm/s // L when P-gain = 100, f_cut = 10Hz L feedforward velocity } if (temp_vel_pos > 0.0f) I_REF_POS = temp_vel_pos * ((double) PISTON_AREA_A * 0.00006f / (K_v * sqrt(2.0f * alpha3 / (alpha3 + 1.0f)))); else I_REF_POS = temp_vel_pos * ((double) PISTON_AREA_B * 0.00006f / (K_v * sqrt(2.0f / (alpha3 + 1.0f)))); // velocity compensation for torque control if ((OPERATING_MODE & 0x01) == 0) { // Rotary Mode I_REF_FORCE_FB = 0.001f * ((double) P_GAIN_JOINT_TORQUE * torq.err + (double) I_GAIN_JOINT_TORQUE * torq.err_sum); // temp_vel_torq = (0.01 * (double) VELOCITY_COMP_GAIN * (double) CUR_VELOCITY / (double) ENC_PULSE_PER_POSITION) * PI / 180.0; // rad/s temp_vel_torq = (0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / (double) ENC_PULSE_PER_POSITION) * PI / 180.0f; // rad/s // L feedforward velocity } else if ((OPERATING_MODE & 0x01) == 1) { I_REF_FORCE_FB = 0.001f * 0.01f*((double) P_GAIN_JOINT_TORQUE * torq.err + (double) I_GAIN_JOINT_TORQUE * torq.err_sum); // Linear Actuators are more sensitive. // temp_vel_torq = (0.01 * (double) VELOCITY_COMP_GAIN * (double) CUR_VELOCITY / (double) ENC_PULSE_PER_POSITION); // mm/s temp_vel_torq = (0.01f * (double) VELOCITY_COMP_GAIN * vel.ref / (double) ENC_PULSE_PER_POSITION); // mm/s // L feedforward velocity } if (temp_vel_torq > 0.0f) I_REF_VC = temp_vel_torq * ((double) PISTON_AREA_A * 0.00006f / (K_v * sqrt(2.0f * alpha3 / (alpha3 + 1.0f)))); else I_REF_VC = temp_vel_torq * ((double) PISTON_AREA_B * 0.00006f / (K_v * sqrt(2.0f / (alpha3 + 1.0f)))); // L velocity(rad/s or mm/s) >> I_ref(mA) // Ref_Joint_FT_dot = (Ref_Joint_FT_Nm - Ref_Joint_FT_Nm_old) / TMR_DT_5k; // Ref_Joint_FT_Nm_old = Ref_Joint_FT_Nm; I_REF = (1.0f - alpha_trans) * I_REF_POS + alpha_trans * (I_REF_VC + I_REF_FORCE_FB); // Anti-windup for FT if (I_GAIN_JOINT_TORQUE != 0) { double I_MAX = 10.0f; // Maximum Current : 10mV double Ka = 2.0f / ((double) I_GAIN_JOINT_TORQUE * 0.001f); if (I_REF > I_MAX) { double I_rem = I_REF - I_MAX; I_rem = Ka*I_rem; I_REF = I_MAX; torq.err_sum = torq.err_sum - I_rem /(float) TMR_FREQ_5k; } else if (I_REF < -I_MAX) { double I_rem = I_REF - (-I_MAX); I_rem = Ka*I_rem; I_REF = -I_MAX; torq.err_sum = torq.err_sum - I_rem /(float) TMR_FREQ_5k; } } } else { float VALVE_POS_RAW_FORCE_FB = 0.0f; float VALVE_POS_RAW_FORCE_FF = 0.0f; float VALVE_POS_RAW = 0.0f; VALVE_POS_RAW_FORCE_FB = alpha_trans*(((float) P_GAIN_JOINT_TORQUE * torq.err + (float) I_GAIN_JOINT_TORQUE * torq.err_sum + (float) D_GAIN_JOINT_TORQUE * (torq.ref_diff - torq_dot.sen)) * 0.01f + DDV_JOINT_POS_FF(vel.sen))+ (1.0f-alpha_trans) * (P_GAIN_JOINT_POSITION * 0.01f * pos.err + DDV_JOINT_POS_FF(vel.ref)); VALVE_POS_RAW_FORCE_FF = P_GAIN_JOINT_TORQUE_FF * torq_ref * 0.001f + D_GAIN_JOINT_TORQUE_FF * (torq_ref - torq_ref_past) * 0.0001f; VALVE_POS_RAW = VALVE_POS_RAW_FORCE_FB + VALVE_POS_RAW_FORCE_FF; if (VALVE_POS_RAW >= 0) { valve_pos.ref = VALVE_POS_RAW + VALVE_DEADZONE_PLUS; } else { valve_pos.ref = VALVE_POS_RAW + VALVE_DEADZONE_MINUS; } if(I_GAIN_JOINT_TORQUE != 0) { double Ka = 2.0f / (double) I_GAIN_JOINT_TORQUE * 100.0f; if(valve_pos.ref>VALVE_MAX_POS) { double valve_pos_rem = valve_pos.ref - VALVE_MAX_POS; valve_pos_rem = valve_pos_rem * Ka; valve_pos.ref = VALVE_MAX_POS; torq.err_sum = torq.err_sum - valve_pos_rem/(float) TMR_FREQ_5k; } else if(valve_pos.ref < VALVE_MIN_POS) { double valve_pos_rem = valve_pos.ref - VALVE_MIN_POS; valve_pos_rem = valve_pos_rem * Ka; valve_pos.ref = VALVE_MIN_POS; torq.err_sum = torq.err_sum - valve_pos_rem/(float) TMR_FREQ_5k; } } VALVE_POS_CONTROL(valve_pos.ref); // Vout.ref = (float) P_GAIN_JOINT_POSITION * 0.01f * ((float) pos.err); V_out = (float) Vout.ref; } torq_ref_past = torq_ref; break; } case MODE_VALVE_OPEN_LOOP: { V_out = (float) Vout.ref; break; } case MODE_JOINT_ADAPTIVE_BACKSTEPPING: { float Va = (1256.6f + Amm * pos.sen/(float)(ENC_PULSE_PER_POSITION)) * 0.000000001f; // 4mm pipe * 100mm + (25mm Cylinder 18mm Rod) * x, unit : m^3 float Vb = (1256.6f + Amm * (79.0f - pos.sen/(float)(ENC_PULSE_PER_POSITION))) * 0.000000001f; // 4mm pipe * 100mm + (25mm Cylinder 18mm Rod) * (79.0mm-x), unit : m^3 V_adapt = 1.0f / (1.0f/Va + 1.0f/Vb); //initial 0.0000053f //float f3 = -Amm*Amm*beta*0.000001f*0.000001f/V_adapt * vel.sen/(float)(ENC_PULSE_PER_POSITION)*0.001f; // unit : N/s //xdot=10mm/s일때 -137076 float f3_hat = -a_hat * vel.sen/(float)(ENC_PULSE_PER_POSITION)*0.001f; // unit : N/s //xdot=10mm/s일때 -137076 float g3_prime = 0.0f; if (torq.sen > Amm*(Ps-Pt)*0.000001f) { g3_prime = 1.0f; } else if (torq.sen < -Amm*(Ps-Pt)*0.000001f) { g3_prime = -1.0f; } else { if ((value-VALVE_CENTER) > 0) { g3_prime = sqrt(Ps-Pt-torq.sen/Amm*1000000.0f); // g3_prime = sqrt(Ps-Pt); } else { g3_prime = sqrt(Ps-Pt+torq.sen/Amm*1000000.0f); // g3_prime = sqrt(Ps-Pt); } } float tau = 0.01f; float K_valve = 0.0004f; float x_v = 0.0f; //x_v : -1~1 if(value>=VALVE_CENTER) { x_v = 1.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MAX_POS - (double)VALVE_CENTER); } else { x_v = -1.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MIN_POS - (double)VALVE_CENTER); } float f4 = -x_v/tau; float g4 = K_valve/tau; float torq_ref_dot = torq.ref_diff * 500.0f; pos.err = (pos.ref - pos.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm] vel.err = (0.0f - vel.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm/s] pos.err_sum += pos.err/(float) TMR_FREQ_5k; //[mm] torq.err = torq.ref - torq.sen; //[N] torq.err_sum += torq.err/(float) TMR_FREQ_5k; //[N] float k3 = 2000.0f; //2000 //20000 float k4 = 10.0f; float rho3 = 3.2f; float rho4 = 10000000.0f; //25000000.0f; float x_4_des = (-f3_hat + torq_ref_dot - k3*(-torq.err))/(gamma_hat*g3_prime); if (x_4_des > 1) x_4_des = 1; else if (x_4_des < -1) x_4_des = -1; if (x_4_des > 0) { valve_pos.ref = x_4_des * (float)(VALVE_MAX_POS - VALVE_CENTER) + (float) VALVE_CENTER; } else { valve_pos.ref = x_4_des * (float)(VALVE_CENTER - VALVE_MIN_POS) + (float) VALVE_CENTER; } float x_4_des_dot = (x_4_des - x_4_des_old)*(float) TMR_FREQ_5k; x_4_des_old = x_4_des; float V_input = 0.0f; V_out = (-f4 + x_4_des_dot - k4*(x_v-x_4_des)- rho3/rho4*gamma_hat*g3_prime*(-torq.err))/g4; // //V_out LPF // float alpha_V_out = 1.0f/(1.0f + 5000.0f/(2.0f*3.14f*50.0f)); // f_cutoff : 50Hz // V_out = V_out*(1.0f-alpha_V_out)+V_input*(alpha_V_out); // float rho_gamma = 5000.0f;//5000 for change //50000 for not change // float gamma_hat_dot = rho3*(-torq.err)/rho_gamma*((-f3+torq_ref_dot-k3*(-torq.err))/gamma_hat + g3_prime*(x_v-x_4_des)); // gamma_hat = gamma_hat + gamma_hat_dot / (float) TMR_FREQ_5k; // // if(gamma_hat > 10000.0f) gamma_hat = 10000.0f; // else if(gamma_hat < 100.0f) gamma_hat = 100.0f; float rho_a = 0.00001f; float a_hat_dot = -rho3/rho_a*vel.sen/(float)(ENC_PULSE_PER_POSITION)*0.001f*(-torq.err); a_hat = a_hat + a_hat_dot / (float) TMR_FREQ_5k; if(a_hat > -3000000.0f) a_hat = -3000000.0f; else if(a_hat < -30000000.0f) a_hat = -30000000.0f; break; } case MODE_RL: { //t.reset(); //t.start(); // if(LED == 0) LED = 1; // else LED = 0; if (Update_Done_Flag == 1) { //Gather Data on each loop // pos.err = (pos.ref - pos.sen)/(float)(ENC_PULSE_PER_POSITION); //[mm] // train_set_x[RL_timer] = pos.sen/(float)(ENC_PULSE_PER_POSITION)/35.0f - 1.0f; //-1.0~1.0 // train_set_error[RL_timer] = pos.err/70.0f; //-1.0~1.0 pos.err = pos.sen/(float)(ENC_PULSE_PER_POSITION) - virt_pos; //[mm] train_set_x[RL_timer] = virt_pos/70.0f; //-1.0~1.0 train_set_error[RL_timer] = pos.err/70.0f; //-1.0~1.0 //train_set_count[RL_timer] = (float) RL_timer / (batch_size *num_batch); //-1.0~1.0 //float temp_array[3] = {train_set_x[RL_timer], train_set_error[RL_timer], train_set_count[RL_timer]}; float temp_array[2] = {train_set_x[RL_timer], train_set_error[RL_timer]}; Actor_Network(temp_array); for (int i=0; i<num_hidden_unit1; i++) { hx_a_sum_array[RL_timer][i] = hx_a_sum[i]; } for (int i=0; i<num_hidden_unit2; i++) { hxh_a_sum_array[RL_timer][i] = hxh_a_sum[i]; } hxhh_a_sum_array[RL_timer][0] = hxhh_a_sum[0]; hxhh_a_sum_array[RL_timer][1] = hxhh_a_sum[1]; mean_array[RL_timer] = mean; deviation_array[RL_timer] = deviation; action_array[RL_timer] = rand_normal(mean_array[RL_timer], deviation_array[RL_timer]); virt_pos = virt_pos + (action_array[RL_timer] - 5.0f) * 1000.0f * 0.0002f; if (virt_pos > 70 ) { virt_pos = 70.0f; } else if(virt_pos < -70) { virt_pos = -70.0f; } RL_timer++; if (RL_timer >= batch_size) { RL_timer = 0; batch++; for(int i=0; i<batch_size; i++) { state_array[i][0] = train_set_x[i]; state_array[i][1] = train_set_error[i]; //state_array[i][2] = train_set_count[i]; } Update_Case = 1; Update_Done_Flag = 0; logging1 = virt_pos; if(batch >= num_batch) { batch = 0; RL_timer = 0; Update_Case = 2; Update_Done_Flag = 0; virt_pos = 10.0f; } } } else { pos.err = pos.sen/(float)(ENC_PULSE_PER_POSITION) - virt_pos; //[mm] float temp_array[3] = {0.0f}; temp_array[0] = virt_pos/70.0f; //-1.0~1.0 temp_array[1] = pos.err/70.0f; //-1.0~1.0 //temp_array[2] = (float) RL_timer / (batch_size *num_batch); //-1.0~1.0 Actor_Network(temp_array); action = rand_normal(mean, deviation); //logging1 = action; //logging2 = mean; //logging4 = deviation; virt_pos = virt_pos + (action-5.0f) * 1000.0f * 0.0002f; if (virt_pos > 70) { virt_pos = 70.0f; } else if(virt_pos < -70) { virt_pos = -70.0f; } logging3 = virt_pos; } //t.stop(); //logging1 = t.read()*1000.0f; //msec break; } default: break; } if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve //////////////////////////////////////////////////////////////////////////// //////////////////////////// CURRENT CONTROL ////////////////////////////// //////////////////////////////////////////////////////////////////////////// if (CURRENT_CONTROL_MODE) { double alpha_update_Iref = 1.0f / (1.0f + 5000.0f / (2.0f * 3.14f * 300.0f)); // f_cutoff : 500Hz I_REF_fil = (1.0f - alpha_update_Iref) * I_REF_fil + alpha_update_Iref*I_REF; I_ERR = I_REF_fil - cur.sen; I_ERR_INT = I_ERR_INT + (I_ERR) * 0.0002f; // Moog Valve Current Control Gain double R_model = 500.0f; // ohm double L_model = 1.2f; double w0 = 2.0f * 3.14f * 150.0f; double KP_I = 0.1f * L_model*w0; double KI_I = 0.1f * R_model*w0; // KNR Valve Current Control Gain if (((OPERATING_MODE & 0b110)>>1) == 1) { // KNR Valve R_model = 163.0f; // ohm L_model = 1.0f; w0 = 2.0f * 3.14f * 80.0f; KP_I = 1.0f * L_model*w0; KI_I = 0.08f * R_model*w0; } double FF_gain = 1.0f; VALVE_PWM_RAW = KP_I * 2.0f * I_ERR + KI_I * 2.0f* I_ERR_INT; // VALVE_PWM_RAW = VALVE_PWM_RAW + FF_gain * (R_model*I_REF); // Unit : mV I_REF_fil_diff = I_REF_fil - I_REF_fil_old; I_REF_fil_old = I_REF_fil; // VALVE_PWM_RAW = VALVE_PWM_RAW + FF_gain * (R_model * I_REF_fil + L_model * I_REF_fil_diff * 5000.0f); // Unit : mV VALVE_PWM_RAW = VALVE_PWM_RAW + FF_gain * (R_model * I_REF_fil); // Unit : mV double V_MAX = 12000.0f; // Maximum Voltage : 12V = 12000mV double Ka = 3.0f / KP_I; if (VALVE_PWM_RAW > V_MAX) { V_rem = VALVE_PWM_RAW - V_MAX; V_rem = Ka*V_rem; VALVE_PWM_RAW = V_MAX; I_ERR_INT = I_ERR_INT - V_rem * 0.0002f; } else if (VALVE_PWM_RAW < -V_MAX) { V_rem = VALVE_PWM_RAW - (-V_MAX); V_rem = Ka*V_rem; VALVE_PWM_RAW = -V_MAX; I_ERR_INT = I_ERR_INT - V_rem * 0.0002f; } Cur_Valve_Open_pulse = cur.sen / mA_PER_pulse; } else { VALVE_PWM_RAW = I_REF * mV_PER_mA; Cur_Valve_Open_pulse = I_REF / mA_PER_pulse; } //////////////////////////////////////////////////////////////////////////// ///////////////// Dead Zone Cancellation & Linearization ////////////////// //////////////////////////////////////////////////////////////////////////// // Dead Zone Cancellation (Mechanical Valve dead-zone) if (FLAG_VALVE_DEADZONE) { if (VALVE_PWM_RAW > 0) VALVE_PWM_RAW = VALVE_PWM_RAW + VALVE_DEADZONE_PLUS * mV_PER_pulse; // unit: mV else if (VALVE_PWM_RAW < 0) VALVE_PWM_RAW = VALVE_PWM_RAW + VALVE_DEADZONE_MINUS * mV_PER_pulse; // unit: mV VALVE_PWM_VALVE_DZ = VALVE_PWM_RAW + (double)VALVE_CENTER * mV_PER_pulse; // unit: mV } else { VALVE_PWM_VALVE_DZ = VALVE_PWM_RAW; } // Output Voltage Linearization double CUR_PWM_nonlin = VALVE_PWM_VALVE_DZ; // Unit : mV double CUR_PWM_lin = PWM_duty_byLT(CUR_PWM_nonlin); // -8000~8000 // Dead Zone Cancellation (Electrical dead-zone) if (CUR_PWM_lin > 0) V_out = (float) (CUR_PWM_lin + 169.0f); else if (CUR_PWM_lin < 0) V_out = (float) (CUR_PWM_lin - 174.0f); else V_out = (float) (CUR_PWM_lin); } else { //////////////////////////sw valve // Output Voltage Linearization // double CUR_PWM_nonlin = V_out; // Unit : mV // double CUR_PWM_lin = PWM_duty_byLT(CUR_PWM_nonlin); // -8000~8000 // Dead Zone Cancellation (Electrical dead-zone) // if (CUR_PWM_lin > 0) V_out = (float) (CUR_PWM_lin + 169.0f); // else if (CUR_PWM_lin < 0) V_out = (float) (CUR_PWM_lin - 174.0f); // else V_out = (float) (CUR_PWM_lin); if (V_out > 0 ) V_out = (V_out + 180.0f)/0.8588f; else if (V_out < 0) V_out = (V_out - 200.0f)/0.8651f; else V_out = 0.0f; } // if(V_out > 0.0f) V_out = (float) (V_out + 169.0f); // else if(V_out < 0.0f) V_out = (float) (V_out - 174.0f); // else V_out = V_out; /******************************************************* *** PWM ********************************************************/ if(DIR_VALVE<0) { V_out = -V_out; } if (V_out >= VALVE_VOLTAGE_LIMIT*1000.0f) { V_out = VALVE_VOLTAGE_LIMIT*1000.0f; } else if(V_out<=-VALVE_VOLTAGE_LIMIT*1000.0f) { V_out = -VALVE_VOLTAGE_LIMIT*1000.0f; } PWM_out= V_out/(SUPPLY_VOLTAGE*1000.0f); // Full duty : 12000.0mV // Saturation of output voltage to 12.0V if(PWM_out > 1.0f) PWM_out=1.0f; else if (PWM_out < -1.0f) PWM_out=-1.0f; if (PWM_out>0.0f) { dtc_v=0.0f; dtc_w=PWM_out; } else { dtc_v=-PWM_out; dtc_w=0.0f; } //pwm TIM4->CCR2 = (PWM_ARR)*(1.0f-dtc_v); TIM4->CCR1 = (PWM_ARR)*(1.0f-dtc_w); /* if (TMR2_COUNT_CAN_TX % (int) ((int) TMR_FREQ_5k/CAN_FREQ) == 0) { // Position, Velocity, and Torque (ID:1200) if (flag_data_request[0] == HIGH) { if ((OPERATING_MODE & 0b01) == 0) { // Rotary Actuator if (SENSING_MODE == 0) { CAN_TX_POSITION_FT((int16_t) (pos.sen), (int16_t) (vel.sen/10.0f), (int16_t) (torq.sen*10.0f)); } else if (SENSING_MODE == 1) { CAN_TX_POSITION_PRESSURE((int16_t) (pos.sen), (int16_t) (vel.sen/10.0f), (int16_t) ((pres_A.sen)*5.0f), (int16_t) ((pres_B.sen)*5.0f)); } } else if ((OPERATING_MODE & 0b01) == 1) { // Linear Actuator if (SENSING_MODE == 0) { CAN_TX_POSITION_FT((int16_t) (pos.sen/10.0f), (int16_t) (vel.sen/256.0f), (int16_t) (torq.sen * 10.0f * (float)(TORQUE_SENSOR_PULSE_PER_TORQUE))); } else if (SENSING_MODE == 1) { CAN_TX_POSITION_PRESSURE((int16_t) (pos.sen/10.0f), (int16_t) (vel.sen/256.0f), (int16_t) ((pres_A.sen)*5.0f), (int16_t) ((pres_B.sen)*5.0f)); } } } if (flag_data_request[1] == HIGH) { CAN_TX_TORQUE((int16_t) (return_G[0]*100.0f)); //1300 } if (flag_data_request[2] == HIGH) { double t_value = 0.0f; if(value>=(float) VALVE_CENTER) { t_value = 10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MAX_POS - (double)VALVE_CENTER); } else { t_value = -10000.0f*((double)value - (double)VALVE_CENTER)/((double)VALVE_MIN_POS - (double)VALVE_CENTER); } double t_value_ref = 0.0f; if(valve_pos.ref>=(float) VALVE_CENTER) { t_value_ref = 10000.0f*((double)valve_pos.ref - (double)VALVE_CENTER)/((double)VALVE_MAX_POS - (double)VALVE_CENTER); } else { t_value_ref = -10000.0f*((double)valve_pos.ref - (double)VALVE_CENTER)/((double)VALVE_MIN_POS - (double)VALVE_CENTER); } CAN_TX_PRES((int16_t) (t_value), (int16_t) (t_value_ref)); // 1400 } //If it doesn't rest, below can can not work. for (int can_rest = 0; can_rest < 10000; can_rest++) { ; } if (flag_data_request[3] == HIGH) { //PWM CAN_TX_PWM((int16_t) (torq.ref)); //1500 // CAN_TX_PWM((int16_t) (f_future[1])); //1500 } if (flag_data_request[4] == HIGH) { //valve position //CAN_TX_VALVE_POSITION((int16_t) pos.sen/(float)(ENC_PULSE_PER_POSITION), (int16_t) virt_pos, (int16_t) (logging2*1000.0f), (int16_t) (logging4*1000.0f)); //1600 CAN_TX_VALVE_POSITION((int16_t) (a_hat*0.0001f), (int16_t) 0, (int16_t) 0, (int16_t) 0); //1600 } // Others : Reference position, Reference FT, PWM, Current (ID:1300) if (flag_data_request[1] == HIGH) { CAN_TX_SOMETHING((int) (FORCE_VREF), (int16_t) (1), (int16_t) (2), (int16_t) (3)); } if (flag_delay_test == 1){ CAN_TX_PRES((int16_t) (0),(int16_t) torq_ref); } TMR2_COUNT_CAN_TX = 0; } TMR2_COUNT_CAN_TX++; */ } TIM3->SR = 0x0; // reset the status register }