$B%j%9%H(B2-5-5.txt

$B"#%j%9%H(B2-5-5$B"#(B

$B!|%a%$%s!!(Bmain.cpp

#include "mbed.h"
#include "sub.hpp"
#include "FIR_LPF.hpp"
#include "notch.hpp"

int main(){
    common_setup();
    xbee.baud(38400);
    xbee.attach(&rx_fifoset, xbee.RxIrq);
    timer_setup.attach_us(&timer_interrupt, 5); // 5usec
    while(1){
        tx_fifo_check();
        if(timer_value[1] > 19){ // 0.1msec sampling
            timer_value[1] = 0;
            float data1 = (float)gain * (analog_value2.read() - 0.5f);  // A/D in (3)
            if(emergence!=0 && data1<0.05 && data1>0.95){
                data1 = old_1;
                if(++em_count1 > 10){
                    em_count1 = 0;
                    tx_message(0xff0000);   // Emergency 1
                }
            }
            if(data1 < 0) data1 = -data1; // always detection ON
            if(fir_lpf != 0) data1 = FIR_calc1(data1);      // FIR calc (1) call
            if(notch_1 != 0) data1 = notch_filter1(data1);
            old_1 = data1;
            if(timer_value[2] > 2999){  // 15msec
                timer_value[2] = 0;
                if(max_count != 0) data1 = move_mean_calc1(data1);
                tx_message((uint16_t)((data1 + 1.0f) * 2047)<<4);
            }
        }
        if(timer_value[3] > 19){ // 0.1msec sampling
            timer_value[3] = 0;
            float data2 = (float)gain * (analog_value3.read() - 0.5f);  // A/D in (4)
            if(emergence!=0 && data2<0.05 && data2>0.95){
                data2 = old_2;
                if(++em_count2 > 10){
                    em_count2 = 0;
                    tx_message(0xff0001);   // Emergency 2
                }
            }
            if(data2 < 0) data2 = -data2; // always detection ON
            if(fir_lpf != 0) data2 = FIR_calc2(data2);      // FIR calc (1) call
            if(notch_2 != 0) data2 = notch_filter2(data2);
            old_2 = data2;
            if(timer_value[4] > 2999){  // 15msec
                timer_value[4] = 0;
                if(max_count != 0) data2 = move_mean_calc2(data2);
                tx_message(0x400000 + ((uint16_t)((data2 + 1.0f) * 2047)<<4));
            }
        }
        if(timer_value[0] > 199999){ // 1000msec
            timer_value[0] = 0;
            myled = !myled;
        }
        if(rx_fifo_check() == 1){
            int sum = 0;
            for (int i=0; i<6; i++) sum += conv_hex(raw_data[i])<<(4*(5-i));
            tx_message(sum); // Echo Back 
            if(sum>>16 == 0x80){
                switch((sum & 0xff00)>>8){
                    case 0x00:
                        fir_lpf = sum & 0x01;
                        break;
                    case 0x01:
                        gain = sum & 0x0f;
                        break;
                    case 0x02:
                        max_count = sum & 0x7f;
                        if (max_count>100) max_count = 100;
                        sum_clear();
                        break;
                    case 0x03:
                        notch_1 = sum & 0x01;
                        break;
                    case 0x04:
                        notch_2 = sum & 0x01;
                        break;
                    case 0x05:
                        coef_set(sum & 0x3f);
                        break;
                    case 0x06:
                        emergence = sum & 0x01;
                        break;
                }
            }
        }        
    }
}

$B!|%5%V(B notch.hpp

/*
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
int main(){
    int fs = 10000;
    double  B0, a1, a2, b1, c0, F0, T;
    F0 = 60;    // or 50
    B0 = 100.;
    T  = 1./fs;
    a1 = 2. * exp(-M_PI * B0 * T) * cos(2. * M_PI * F0 * T);
    a2 = -exp(-2. * M_PI * B0 * T);
    b1 = -2. * cos(2. * M_PI * F0 * T);
    c0 = (1-a1-a2)/(2+b1);
    printf("a1 = %f\n", a1);
    printf("a2 = %f\n", a2);
    printf("b1 = %f\n", b1);
    printf("c0 = %f\n", c0);
    return 0;
}
60Hz
    a1 = 1.936768
    a2 = -0.939101
    b1 = -1.998579
    c0 = 1.642174
50Hz
    a1 = 1.937188
    a2 = -0.939101
    b1 = -1.999013
    c0 = 1.938304
*/

float notch_filter1(float data){
    y1[0] = data + a1*y1[1] + a2*y1[2];
    float reault = y1[0] + b1*y1[1] + y1[2];
    y1[2] = y1[1];
    y1[1] = y1[0];
    return(reault);
}

float notch_filter2(float data){
    y2[0] = data + a1*y2[1] + a2*y2[2];
    float reault = y2[0] + b1*y2[1] + y2[2];
    y2[2] = y2[1];
    y2[1] = y2[0];
    return(reault);
}

$B!|%5%V(B sub.hpp

unsigned char rxFIFO[256], txFIFO[256], raw_data[6];
unsigned char rx_top, rx_end, tx_top, tx_end, phase;
float mean_sum1, mean_sum2, ad_data1[101], ad_data2[101];
int timer_value[6], max_count, fir_lpf, gain, ad_pointer1, ad_pointer2;
const int order = 200;
float xn1[order+1], xn2[order+1];
float a1, a2, b1, c0, y1[3], y2[3], old_1, old_2;
int notch_1, notch_2, emergence, em_count1, em_count2;
const float _60Hz_a1 = 1.936768, _60Hz_a2 = -0.939101, _60Hz_b1 = -1.998579, _60Hz_c0 = 1.642174;
const float _50Hz_a1 = 1.937188, _50Hz_a2 = -0.939101, _50Hz_b1 = -1.999013, _50Hz_c0 = 1.938304;

RawSerial xbee(PA_2, PA_3);
Ticker timer_setup;
AnalogIn analog_value0(A0);
AnalogIn analog_value1(A1);
AnalogIn analog_value2(A2);
AnalogIn analog_value3(A3);
DigitalOut myled(LED1);

void sum_clear(){
    int i;
    for (i=0; i<101; i++) ad_data1[i] = ad_data2[i] = 0;
    ad_pointer1 = ad_pointer2 = mean_sum1 = mean_sum2 = 0;
}

void coef_set(int herz){
    if(herz < 55){
        a1 = _50Hz_a1;
        a2 = _50Hz_a2;
        b1 = _50Hz_b1;
        c0 = _50Hz_c0;
    }
    else{
        a1 = _60Hz_a1;
        a2 = _60Hz_a2;
        b1 = _60Hz_b1;
        c0 = _60Hz_c0;
    }
    for (int i=0; i<3; i++) y1[i] = y2[i] = 0;
}
void common_setup(){
    int i;
    rx_top = rx_end = tx_top = tx_end = phase = 0;
    em_count1 = em_count2 = 0;
    max_count = 100;
    fir_lpf = emergence = old_1 = old_2 = 0;
    gain = 5;
    for (i=0; i<3; i++) timer_value[i] = 0;
    timer_value[3] = 10;
    timer_value[4] = 1500;
    for (i=0; i<=order; i++) xn1[i] = xn2[i] = 0.0;
    sum_clear();
    notch_1 = notch_2 = 60;
    coef_set(60);
}

void timer_interrupt(){
    int i;
    for (i=0; i<6; i++) timer_value[i]++;
}

void tx_fifo_check(){
    if(xbee.writeable() == 1){
        if(tx_top != tx_end){
            xbee.putc(txFIFO[tx_end]);
            ++tx_end &= 255;
        }
    }
}

int rx_fifo_check(){
    unsigned char data;
    if(rx_top != rx_end){
        data = rxFIFO[rx_end];
        ++rx_end &= 255;
        if (data < 33){
            phase = 0;
            return(1);
        }
        raw_data[phase] = data;
        if(++phase > 5) phase = 0;
        return(0);
    }
    return(0);
}

void rx_fifoset(void){
    rxFIFO[rx_top] = xbee.getc();
    ++rx_top &= 255;
}

void tx_fifoset(unsigned char data){
    txFIFO[tx_top] = data;
    ++tx_top &= 255;
}

unsigned char hex_conv(unsigned char data){
    data &= 15;
    if(data < 10) return(data+48);
    else return(data+55);
}

unsigned char conv_hex(unsigned char data){
    if((data > 47) && (data < 58)) return(data-48);
    else if((data > 64) && (data < 71)) return(data-55);
    return(0);
}

void tx_message(int data){
    int i;
    for (i=0; i<6; i++) tx_fifoset(hex_conv((data>>(4*(5-i))) & 15));
    tx_fifoset(13);
}

float move_mean_calc1(float data){
    mean_sum1 = mean_sum1 - ad_data1[ad_pointer1] + data;
    ad_data1[ad_pointer1] = data;
    ad_pointer1++;
    if(ad_pointer1 == max_count) ad_pointer1 = 0;
    return(mean_sum1 / (float)max_count);
}

float move_mean_calc2(float data){
    mean_sum2 = mean_sum2 - ad_data2[ad_pointer2] + data;
    ad_data2[ad_pointer2] = data;
    ad_pointer2++;
    if(ad_pointer2 == max_count) ad_pointer2 = 0;
    return(mean_sum2 / (float)max_count);
}

$B!|%5%V(B FIR_LPF.hpp

($B%j%9%H(B2-5-2$B$HF1$8(B)

========================
mbed$B%5%$%H(B
http://developer.mbed.org/users/nagasm/code/CQ_nagasm_09_emergency/
$B$K$F8x3+Cf(B
========================
