Sungwoo Kim
for learning
main.cpp
- Committer:
- Lightvalve
- Date:
- 2021-01-06
- Revision:
- 246:d483d039ca55
- Parent:
- 245:3592e0da43fb
- Child:
- 247:87a44e8b3392
File content as of revision 246:d483d039ca55:
//210106_4 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] = {
{0.17958179116249084f,-0.04240188002586365f,0.006034236866980791f,-0.221439927816391f,-0.1701967865228653f,-0.4843500852584839f,-0.327612966299057f,-0.38140514492988586f,-0.24118416011333466f,-2.0342297554016113f,-0.4474838972091675f,0.182233065366745f,-0.07394298911094666f,0.15372516214847565f,-0.5738809108734131f,0.41910025477409363f},
{-0.13663026690483093f,-0.17034339904785156f,-0.505244255065918f,-0.18086491525173187f,0.27973324060440063f,0.08476945012807846f,-0.454378217458725f,-0.23875154554843903f,0.07920899987220764f,-1.0418452024459839f,-0.3546728193759918f,-0.33462417125701904f,-0.470501571893692f,-0.3497585654258728f,-0.4295664429664612f,0.38090988993644714f},
{-0.2616637349128723f,0.2715362012386322f,0.11061228811740875f,-0.049712538719177246f,0.33446288108825684f,0.20204780995845795f,-0.36349689960479736f,0.3688911199569702f,-0.31277671456336975f,-0.8215123414993286f,-0.08787065744400024f,-0.3989328444004059f,0.3128615915775299f,-0.2449539303779602f,-0.3281116783618927f,0.3294149935245514f},
{0.17975585162639618f,-0.06140896677970886f,0.3280285596847534f,-0.4180477559566498f,0.24598084390163422f,0.2129925787448883f,0.31618329882621765f,0.34586048126220703f,0.3941290080547333f,-0.9906793832778931f,-0.005607783794403076f,-0.46453559398651123f,0.35961928963661194f,-1.0205261707305908f,-0.12470138072967529f,-0.35264861583709717f},
{-0.4245941638946533f,-0.25384438037872314f,0.49728941917419434f,-0.0833565890789032f,-0.10983119904994965f,-0.28237199783325195f,0.23235633969306946f,0.1686479151248932f,0.45442262291908264f,0.22290197014808655f,-0.4178416132926941f,0.17834660410881042f,-0.1668587028980255f,-1.1557658910751343f,0.4386714696884155f,0.36624616384506226f},
{0.22955767810344696f,0.052053600549697876f,0.36206480860710144f,-0.2569443881511688f,0.40751034021377563f,-0.15801949799060822f,0.44667890667915344f,0.3191206455230713f,-0.20778316259384155f,2.245435953140259f,-0.2823447585105896f,-0.3264654278755188f,-0.20842257142066956f,-1.6384838819503784f,0.8415021300315857f,0.2748992145061493f},
{0.311470091342926f,-0.1932627558708191f,-1.2633849382400513f,-0.30763253569602966f,-0.7120758295059204f,-0.08423300087451935f,0.349816232919693f,-0.6385902166366577f,0.4183693826198578f,-2.3064849376678467f,0.3213910758495331f,0.36403366923332214f,-0.3816591501235962f,1.8948888778686523f,-2.072500467300415f,-1.3153260946273804f},
{-0.06539730727672577f,-0.12553253769874573f,-1.1188851594924927f,0.2474658042192459f,-0.3314621150493622f,-0.023833077400922775f,-0.12525120377540588f,-0.655504584312439f,-0.4302884340286255f,-1.4577856063842773f,-0.07813754677772522f,-0.45890241861343384f,-0.25786811113357544f,1.5043410062789917f,-1.388866901397705f,-0.4735736548900604f},
{-0.2886306941509247f,-0.24350808560848236f,-0.9309620261192322f,-0.1380021870136261f,-0.5939037203788757f,0.09553308039903641f,0.36275312304496765f,-0.07287690043449402f,-0.24274887144565582f,0.04862043634057045f,0.11128035187721252f,0.16030797362327576f,-0.1772099733352661f,-0.3249896764755249f,0.15046773850917816f,-0.5630593299865723f},
{-0.04409542679786682f,-0.0033446550369262695f,-0.5614001750946045f,0.3355940878391266f,-0.43958982825279236f,-0.14973217248916626f,-0.36208683252334595f,-0.22287395596504211f,0.3304477035999298f,0.5311539173126221f,-0.422980934381485f,-0.4016188979148865f,-0.09530887007713318f,-0.4136705994606018f,0.16326206922531128f,-0.6383588314056396f},
{-0.06942542642354965f,-0.3122544288635254f,-0.2772074341773987f,0.3908238708972931f,-0.7278497815132141f,-0.8595213890075684f,0.28198525309562683f,-0.0052377209067344666f,-0.2356695532798767f,3.927525043487549f,0.3545668423175812f,-0.08922263979911804f,-0.10360953211784363f,-1.7213302850723267f,2.0913679599761963f,-0.520579993724823f},
};
const float h2[16][16] = {
{-0.2620375156402588f,0.37042757868766785f,0.43509164452552795f,0.16807469725608826f,0.15916648507118225f,0.3894948661327362f,-0.32141682505607605f,0.13929973542690277f,-0.34060487151145935f,0.15095087885856628f,-0.344393789768219f,-0.058255635201931f,0.16450373828411102f,0.21836978197097778f,-0.20522934198379517f,-0.27261078357696533f},
{-0.21259629726409912f,0.30915436148643494f,0.015076518058776855f,-0.39902231097221375f,-0.18323884904384613f,-0.25017163157463074f,0.22715261578559875f,0.12961390614509583f,0.062155842781066895f,-0.2879970073699951f,-0.4085868299007416f,-0.11838218569755554f,0.26664987206459045f,-0.39286932349205017f,0.10185262560844421f,0.179502934217453f},
{-0.03793885186314583f,-0.3573683798313141f,0.06097343564033508f,-0.252775639295578f,-0.37151437997817993f,-0.013271182775497437f,-0.45967423915863037f,0.10316108167171478f,-0.11774859577417374f,0.5462096333503723f,-0.18710604310035706f,-0.029353726655244827f,-0.24944661557674408f,-0.2652386724948883f,0.3322176933288574f,-0.16139188408851624f},
{0.22759874165058136f,0.22665467858314514f,-0.08438774198293686f,-0.09153807163238525f,-0.4037201702594757f,-0.13536912202835083f,0.1031552106142044f,0.17077112197875977f,-0.22907809913158417f,-0.08447431027889252f,-0.2665717601776123f,0.0590270459651947f,0.240172877907753f,-0.036954399198293686f,-0.2624008059501648f,0.34289684891700745f},
{0.22408106923103333f,0.003781914710998535f,-0.003097875276580453f,0.012549430131912231f,0.05206727981567383f,0.1991729438304901f,-0.10661765933036804f,-0.1637379676103592f,0.4511772394180298f,0.32293254137039185f,-0.3264670968055725f,0.4172098636627197f,0.26955217123031616f,-0.3135477304458618f,-0.017087146639823914f,-0.13685491681098938f},
{-0.10098368674516678f,-0.31099092960357666f,-0.35130780935287476f,-0.035713016986846924f,0.3840901553630829f,-0.07895198464393616f,-0.3359406888484955f,0.13158081471920013f,-0.264556884765625f,-0.20730061829090118f,-0.3289949893951416f,-0.37881767749786377f,0.22396403551101685f,0.324337363243103f,-0.07941572368144989f,0.3288460075855255f},
{-0.08396893739700317f,-0.2486235648393631f,0.11694523692131042f,-0.3298819065093994f,0.2805224359035492f,-0.33067765831947327f,0.16457203030586243f,-0.24889105558395386f,-0.3972022235393524f,-0.4223710894584656f,-0.07348325848579407f,-0.14260199666023254f,-0.07233420014381409f,0.31599655747413635f,-0.2761499881744385f,-0.14283323287963867f},
{0.10991116613149643f,0.03272828459739685f,0.3384140133857727f,0.24620458483695984f,-0.2754482626914978f,-0.20292288064956665f,-0.38267478346824646f,0.4620051681995392f,0.5180315375328064f,0.3701077997684479f,-0.07301062345504761f,0.24291732907295227f,0.1819831132888794f,-0.338138222694397f,0.32491427659988403f,-0.11201971769332886f},
{-0.139004647731781f,0.0766352117061615f,0.15332308411598206f,0.09886243939399719f,0.415459007024765f,-0.2532200515270233f,-0.20159946382045746f,0.21463772654533386f,-0.3405895531177521f,-0.3144799768924713f,-0.26305460929870605f,-0.09823668003082275f,0.10379686951637268f,-0.3907162845134735f,0.06197598576545715f,-0.4297400414943695f},
{-2.4657206535339355f,-0.5663966536521912f,0.39645668864250183f,-2.7376959323883057f,-0.3138399124145508f,-0.23994505405426025f,0.09061788022518158f,-0.018074365332722664f,-0.809702455997467f,-0.21874652802944183f,2.676147222518921f,-0.045667391270399094f,-0.245742067694664f,-1.3836430311203003f,0.07703496515750885f,0.013621658086776733f},
{0.358629435300827f,0.2196318805217743f,-0.16727790236473083f,-0.213405579328537f,0.26773831248283386f,-0.001271277666091919f,0.067145437002182f,-0.3299995958805084f,-0.13708710670471191f,-0.19961315393447876f,-0.3892948031425476f,-0.20604045689105988f,0.2654934227466583f,-0.24381771683692932f,-0.05982998013496399f,-0.0015056133270263672f},
{0.2640920579433441f,-0.22446219623088837f,-0.2886914610862732f,0.3683915436267853f,-0.36545583605766296f,0.30690982937812805f,0.026461631059646606f,0.20954808592796326f,-0.37727683782577515f,-0.017216116189956665f,0.33506569266319275f,-0.08547034859657288f,-0.3837997317314148f,0.3110499083995819f,0.023928165435791016f,0.11103644967079163f},
{-0.05501928925514221f,-0.03194811940193176f,-0.3095245361328125f,-0.3765944242477417f,-0.08870676159858704f,-0.38370949029922485f,0.27549585700035095f,-0.1704704463481903f,-0.15534046292304993f,-0.029324114322662354f,0.30144771933555603f,0.1282394826412201f,-0.4146917164325714f,0.05758216977119446f,-0.12351158261299133f,0.33150044083595276f},
{-6.269066333770752f,-0.4840625524520874f,-0.8029376268386841f,1.4539271593093872f,-0.2583809196949005f,0.06044796109199524f,5.5765461921691895f,-0.463117390871048f,-2.973649024963379f,-1.709280252456665f,1.1793328523635864f,-1.4464561939239502f,0.11601023375988007f,-1.2080674171447754f,-0.4982510507106781f,-0.018069803714752197f},
{-0.5226690769195557f,0.024054784327745438f,0.3043413758277893f,-0.21406987309455872f,0.048102229833602905f,0.3183996379375458f,-2.242119550704956f,-2.4457921981811523f,1.1343311071395874f,0.8771806955337524f,-0.09124940633773804f,-0.01114705577492714f,-0.09407463669776917f,-0.6493850946426392f,0.6204522848129272f,0.40590086579322815f},
{0.4078655242919922f,-0.021884441375732422f,0.7078089714050293f,-0.4147486984729767f,-0.22760425508022308f,-0.21837124228477478f,-0.6915476322174072f,0.400470107793808f,1.3295509815216064f,0.6675918102264404f,-0.22325173020362854f,0.31319117546081543f,0.19979795813560486f,0.09075940400362015f,-0.07419884204864502f,0.4099201261997223f},
};
const float h3[16][16] = {
{0.5000174045562744f,-0.3934583067893982f,3.2444660663604736f,0.16543321311473846f,-0.2896377444267273f,0.4315599501132965f,-0.24898718297481537f,0.3502558171749115f,0.038538217544555664f,-1.1473206281661987f,0.13260938227176666f,-3.1099228858947754f,-2.579786539077759f,-1.8402668237686157f,-0.35141128301620483f,-1.9576377868652344f},
{-0.19814090430736542f,0.1000506579875946f,0.24856364727020264f,0.16854533553123474f,-0.014051258563995361f,0.21776077151298523f,0.2533715069293976f,0.4361461102962494f,-0.050481975078582764f,-0.2774789035320282f,-0.39193934202194214f,-0.08128736913204193f,-0.36607205867767334f,0.2565839886665344f,-0.2752825617790222f,0.07434240728616714f},
{-0.0989396795630455f,-0.15912768244743347f,0.19554810225963593f,-0.1543317437171936f,-0.010217905044555664f,0.10984447598457336f,-0.8712243437767029f,-0.5927308797836304f,-0.2467522770166397f,-0.5041314959526062f,0.1504158228635788f,-0.705197811126709f,-0.7629088759422302f,-0.7897229790687561f,-0.4989174008369446f,0.07327631115913391f},
{0.756802499294281f,-0.05796456336975098f,-0.5923332571983337f,0.1967080682516098f,-0.28813666105270386f,-0.4127959609031677f,-0.7479408383369446f,0.2776479125022888f,0.2536095678806305f,-0.8013079762458801f,-0.32496610283851624f,0.46975526213645935f,-2.4841690063476562f,0.20107950270175934f,-0.42854803800582886f,2.1080806255340576f},
{0.1314193308353424f,-0.38466498255729675f,-0.15953338146209717f,-0.26907312870025635f,0.042690664529800415f,0.019402503967285156f,0.3272710144519806f,0.2640456259250641f,-0.20614370703697205f,-0.09802588820457458f,0.13658878207206726f,-0.05913272500038147f,-0.10392564535140991f,0.09841910004615784f,0.34520223736763f,0.18591228127479553f},
{0.11987492442131042f,0.3606952130794525f,0.40429654717445374f,-0.4004298746585846f,-0.26991036534309387f,-0.3640212416648865f,0.1257953941822052f,-0.08500143885612488f,-0.16398006677627563f,0.08932033181190491f,0.2442457377910614f,-0.20674392580986023f,0.35870078206062317f,0.11110439896583557f,-0.20613843202590942f,-0.39209720492362976f},
{-2.6611971855163574f,-0.539090096950531f,-1.5071735382080078f,-0.12003330141305923f,-0.12599343061447144f,-0.3494933545589447f,-2.1951372623443604f,-1.278491497039795f,0.02455461025238037f,-2.221325159072876f,-0.3452872335910797f,-1.6981240510940552f,-2.151801824569702f,-3.2274301052093506f,-0.4008919596672058f,0.962826132774353f},
{-0.41465306282043457f,0.23161640763282776f,0.4639943540096283f,-0.4577018916606903f,-0.24190503358840942f,-0.1998729109764099f,0.09550302475690842f,-0.017417212948203087f,-0.06523853540420532f,0.27713626623153687f,-0.14726893603801727f,-0.18674850463867188f,-0.21913161873817444f,-0.24818894267082214f,0.3062843978404999f,-0.3072904646396637f},
{-0.892498791217804f,0.0581616647541523f,0.15531174838542938f,-0.1323482245206833f,-0.3804210424423218f,-0.0036951005458831787f,-0.4520958960056305f,-0.9942843914031982f,0.3564160168170929f,0.2842966914176941f,-0.511879563331604f,-1.1283612251281738f,0.29649484157562256f,-0.7170117497444153f,-0.521460235118866f,-1.1580941677093506f},
{-0.711818277835846f,-0.2637007236480713f,0.5674629211425781f,0.210587278008461f,0.26736071705818176f,-0.4109957814216614f,-0.916969358921051f,-0.076946921646595f,-0.05028003454208374f,-0.10429365932941437f,0.1912822425365448f,-0.8557406663894653f,0.834824800491333f,-0.8409402370452881f,0.236328586935997f,-0.47351527214050293f},
{-3.8374710083007812f,-0.11407425999641418f,0.14006337523460388f,0.17107561230659485f,-0.33362388610839844f,0.30166277289390564f,-0.25330066680908203f,-0.1871817260980606f,-0.24762524664402008f,-0.3609272837638855f,-0.07041087746620178f,-0.8773161768913269f,-0.24865493178367615f,-0.06128392368555069f,-0.13219350576400757f,-1.9361486434936523f},
{-0.05882857367396355f,-0.2733021080493927f,0.21617934107780457f,-0.30629611015319824f,0.07898566126823425f,0.2287261188030243f,0.02701757103204727f,0.3264598846435547f,-0.2693949043750763f,-0.2334243357181549f,0.1090087965130806f,-0.638395369052887f,-0.4086129665374756f,-0.46797919273376465f,0.22190247476100922f,0.20755542814731598f},
{-0.2160346508026123f,-0.25015729665756226f,0.3509782552719116f,0.27520814538002014f,0.06877782940864563f,-0.16420304775238037f,-0.13360756635665894f,0.17819254100322723f,0.3542599380016327f,-0.39976000785827637f,0.15226706862449646f,0.03759896010160446f,-0.192609965801239f,0.3178251385688782f,0.376699298620224f,-0.03706258907914162f},
{-0.4376278817653656f,-0.39521247148513794f,-0.052698906511068344f,0.045695118606090546f,0.18373921513557434f,-0.07091012597084045f,0.48824018239974976f,-0.09644247591495514f,-0.26085102558135986f,-0.4012276828289032f,-0.3096748888492584f,-0.9042310118675232f,-0.12502725422382355f,-0.5655964612960815f,0.08477383852005005f,-0.6312101483345032f},
{-0.2165888547897339f,-0.2858605980873108f,-0.10608450323343277f,-0.11974962055683136f,0.4085064232349396f,-0.023935168981552124f,-0.49706608057022095f,-0.40255412459373474f,0.2847798764705658f,0.11177223175764084f,-0.08394107967615128f,-0.637089192867279f,-0.3223956525325775f,-0.12196404486894608f,-0.4778788089752197f,-0.2488020360469818f},
{-0.3151550590991974f,0.3430427014827728f,0.10783877968788147f,0.23641803860664368f,-0.20377427339553833f,0.3869435489177704f,0.2664237320423126f,-0.3614561855792999f,-0.41822370886802673f,-0.1094929575920105f,0.36601582169532776f,-0.22730733454227448f,-0.3357813358306885f,0.02511197328567505f,-0.22192305326461792f,-0.03697633743286133f},
};
const float hout[16] = { 0.9916985034942627f,0.0779474526643753f,-0.059218667447566986f,0.28552961349487305f,0.4177809953689575f,0.10823440551757812f,1.7049182653427124f,1.4367884397506714f,0.26246923208236694f,1.1129926443099976f,0.021266205236315727f,1.8224459886550903f,1.6953108310699463f,0.9579318165779114f,0.08610948920249939f,-0.20108376443386078f };
const float b1[16] = { 0.0904887393116951f,-0.09911143034696579f,0.9018362760543823f,-0.16343198716640472f,0.03011699579656124f,0.4689757823944092f,-0.5947720408439636f,-0.3204752504825592f,-1.0864993333816528f,2.02054500579834f,-0.3855648636817932f,-0.42363351583480835f,0.3849257826805115f,3.7228715419769287f,0.24543751776218414f,-0.07794411480426788f };
const float b2[16] = { -0.01568278670310974f,-0.19216857850551605f,-0.6542280316352844f,0.5167033672332764f,-0.6799002289772034f,-1.1810632944107056f,0.30047011375427246f,-0.20442862808704376f,-0.739217221736908f,-0.6231285929679871f,-0.5815446972846985f,-0.2541882395744324f,-0.23933610320091248f,-0.07090947777032852f,-0.7687814831733704f,-0.5511945486068726f };
const float b3[16] = { 1.0354466438293457f,-0.3245743215084076f,-0.8153882622718811f,-0.8336290717124939f,-0.7861266732215881f,-1.8031482696533203f,0.24558615684509277f,0.9596911668777466f,-1.0300992727279663f,-0.0033117507118731737f,-0.05127987638115883f,-0.024405304342508316f,0.40189796686172485f,0.4642368257045746f,-0.03082113526761532f,0.7068071365356445f };
const float bout[1] = { 0.6253164410591125f };
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
}