albatross
今までのジョイスティックの入力を段階分けしていた方式から、アナログ値をできる限りそのまま使用する方式に変更しました。
Fork of
ControlMain2017
by 
albatross
main.cpp
- Committer:
- tsumagari
- Date:
- 2017-01-21
- Branch:
- test
- Revision:
- 9:c32999b4d2f9
- Parent:
- 8:dbc8c87dac78
- Child:
- 10:b7159feb11fd
File content as of revision 9:c32999b4d2f9:
//中央can program
#include "mbed.h"
//#include "BufferedSoftSerial.h"
#define WAIT_LOOP_TIME 0.1
#define YOKUTAN_DATAS_NUM 7
#define IMPUT_DATAS_NUM 2
#define SEND_DATAS_CAN_ID 100
#define SEND_DATAS_TIME 0.5
#define THRESHOLD_OH_VALUE 0.14
#define CALC_CADENCE_TIME 0.05
//-----------------------------------(resetInterrupt def)
extern "C" void mbed_reset();
InterruptIn resetPin(p26);
Timer resetTimeCount;
void resetInterrupt(){
while(resetPin){
resetTimeCount.start();
if(resetTimeCount.read()>3) mbed_reset();
}
resetTimeCount.reset();
}
//-------------------------------------------------------
CAN can_R(p30,p29);
CAN can_L(p9,p10);
Serial toKeikiSerial(p13,p14);
//BufferedSoftSerial toKeikiSerial(p17,p18);
Serial pc(USBTX,USBRX);
DigitalIn eruron_R(p22);
DigitalIn eruron_L(p20);
DigitalIn drug_R(p23);
DigitalIn drug_L(p19);
DigitalOut myled1(LED1);
DigitalOut myled2(LED2);
//Ticker sendDatasTicker;
Ticker cadenceTicker;
Timer cadenceTimer;
AnalogIn p(p15);
AnalogIn q(p16);
char yokutanDatas_R[YOKUTAN_DATAS_NUM];
char yokutanDatas_L[YOKUTAN_DATAS_NUM];
char inputDatas_R[IMPUT_DATAS_NUM];
char inputDatas_L[IMPUT_DATAS_NUM];
char cadence = 0;
bool stateP = true;
bool stateQ = true;
bool stateP_old = true;
bool stateQ_old = true;
CANMessage recmsg_R;
CANMessage recmsg_L;
void InputControlValues(){
inputDatas_R[1] = (char)drug_R;
inputDatas_L[1] = (char)drug_L;
if(eruron_R){
inputDatas_R[0] = 0;
inputDatas_L[0] = 2;
}
else if(eruron_L){
inputDatas_R[0] = 2;
inputDatas_L[0] = 0;
}
else{
inputDatas_R[0] = 1;
inputDatas_L[0] = 1;
}
}
void toString_R(){
pc.printf("R:");
for(int i = 0; i < IMPUT_DATAS_NUM; i++){
pc.printf("%d:%i ",i,inputDatas_R[i]);
}
}
void toString_L(){
pc.printf("L:");
for(int i = 0; i < IMPUT_DATAS_NUM; i++){
pc.printf("%d:%i ",i,inputDatas_L[i]);
}
pc.printf("\n\r");
}
void SendDatas(){
can_R.write(CANMessage(SEND_DATAS_CAN_ID, inputDatas_R, IMPUT_DATAS_NUM));
can_L.write(CANMessage(SEND_DATAS_CAN_ID, inputDatas_L, IMPUT_DATAS_NUM));
toKeikiSerial.putc(';');
for(int i = 0; i < YOKUTAN_DATAS_NUM; i++){
// toKeikiSerial.putc(i);
// toKeikiSerial.putc(10+i);
toKeikiSerial.putc(yokutanDatas_R[i]);
toKeikiSerial.putc(yokutanDatas_L[i]);
}
for(int i = 0; i < IMPUT_DATAS_NUM; i++){
// toKeikiSerial.putc(4+i);
// toKeikiSerial.putc(14+i);
toKeikiSerial.putc(inputDatas_R[i]);
toKeikiSerial.putc(inputDatas_L[i]);
}
// toKeikiSerial.putc(cadence);
pc.printf("test\n\r");
}
void calcCadence(){
//pc.printf("%f,%f\n\r",p.read(),q.read());
if(p.read() > THRESHOLD_OH_VALUE) stateP = true;
else stateP = false;
if(q.read() > THRESHOLD_OH_VALUE) stateQ = true;
else stateQ = false;
if((stateP == true && stateP_old == false) ||
stateQ == true && stateQ_old == false){
cadenceTimer.stop();
cadence = (char)30.0/cadenceTimer.read();
pc.printf("Cadence:%i\n\r",cadence);
cadenceTimer.reset();
cadenceTimer.start();
}
stateP_old = stateP;
stateQ_old = stateQ;
}
void init(){
//--------------------------------------(resetInterrupt init)
resetPin.rise(resetInterrupt);
resetPin.mode(PullDown);
//-----------------------------------------------------------
cadenceTimer.start();
cadenceTicker.attach(calcCadence, CALC_CADENCE_TIME);
// sendDatasTicker.attach(SendDatas,SEND_DATAS_TIME);
for(int i = 0; i < IMPUT_DATAS_NUM; i++){
inputDatas_R[i] = 0;
inputDatas_L[i] = 0;
}
}
void receiveDatas(){
if(can_R.read(recmsg_R)){
for(int i = 0; i < recmsg_R.len; i++){
yokutanDatas_R[i] = recmsg_R.data[i];
}
myled1 = !myled1;
}
if(can_L.read(recmsg_L)){
for(int i = 0; i < recmsg_L.len; i++){
yokutanDatas_L[i] = recmsg_L.data[i];
}
myled2 = !myled2;
}
}
int main(){
init();
while(1){
InputControlValues();
wait_us(10);
receiveDatas();
SendDatas();
//toString_R();
// toString_L();
wait(WAIT_LOOP_TIME);
}
}