APS Lab
Uart with ADXL362
My Memo's for EV-COG-AD4050LZ Pinname
<<CODE>> #define GPIO_PORT_SHIFT 12 typedef enum { P0_00 = (0 << GPIO_PORT_SHIFT | 0 ), P0_01 = (0 << GPIO_PORT_SHIFT | 1 ), P0_02 = (0 << GPIO_PORT_SHIFT | 2 ), P0_03 = (0 << GPIO_PORT_SHIFT | 3 ), P0_04 = (0 << GPIO_PORT_SHIFT | 4 ), P0_05 = (0 << GPIO_PORT_SHIFT | 5 ), P0_06 = (0 << GPIO_PORT_SHIFT | 6 ), P0_07 = (0 << GPIO_PORT_SHIFT | 7 ), P0_08 = (0 << GPIO_PORT_SHIFT | 8 ), P0_09 = (0 << GPIO_PORT_SHIFT | 9 ), P0_10 = (0 << GPIO_PORT_SHIFT | 10), P0_11 = (0 << GPIO_PORT_SHIFT | 11), P0_12 = (0 << GPIO_PORT_SHIFT | 12), P0_13 = (0 << GPIO_PORT_SHIFT | 13), P0_14 = (0 << GPIO_PORT_SHIFT | 14), P0_15 = (0 << GPIO_PORT_SHIFT | 15), P1_00 = (1 << GPIO_PORT_SHIFT | 0 ), P1_01 = (1 << GPIO_PORT_SHIFT | 1 ), P1_02 = (1 << GPIO_PORT_SHIFT | 2 ), P1_03 = (1 << GPIO_PORT_SHIFT | 3 ), P1_04 = (1 << GPIO_PORT_SHIFT | 4 ), P1_05 = (1 << GPIO_PORT_SHIFT | 5 ), P1_06 = (1 << GPIO_PORT_SHIFT | 6 ), P1_07 = (1 << GPIO_PORT_SHIFT | 7 ), P1_08 = (1 << GPIO_PORT_SHIFT | 8 ), P1_09 = (1 << GPIO_PORT_SHIFT | 9 ), P1_10 = (1 << GPIO_PORT_SHIFT | 10), P1_11 = (1 << GPIO_PORT_SHIFT | 11), P1_12 = (1 << GPIO_PORT_SHIFT | 12), P1_13 = (1 << GPIO_PORT_SHIFT | 13), P1_14 = (1 << GPIO_PORT_SHIFT | 14), P1_15 = (1 << GPIO_PORT_SHIFT | 15), P2_00 = (2 << GPIO_PORT_SHIFT | 0 ), P2_01 = (2 << GPIO_PORT_SHIFT | 1 ), P2_02 = (2 << GPIO_PORT_SHIFT | 2 ), P2_03 = (2 << GPIO_PORT_SHIFT | 3 ), P2_04 = (2 << GPIO_PORT_SHIFT | 4 ), P2_05 = (2 << GPIO_PORT_SHIFT | 5 ), P2_06 = (2 << GPIO_PORT_SHIFT | 6 ), P2_07 = (2 << GPIO_PORT_SHIFT | 7 ), P2_08 = (2 << GPIO_PORT_SHIFT | 8 ), P2_09 = (2 << GPIO_PORT_SHIFT | 9 ), P2_10 = (2 << GPIO_PORT_SHIFT | 10), P2_11 = (2 << GPIO_PORT_SHIFT | 11), // USB Pins USBTX = P0_10, USBRX = P0_11, USBTX1 = P1_15, USBRX1 = P2_00, // mbed original LED naming LED1 = P2_02, LED2 = P2_10, LED3 = LED2, LED4 = LED1, //Push buttons PB0 = P1_00, // BTN1 PB1 = P0_09, // BTN2 BUTTON1 = P1_00, // BTN1 BUTTON2 = P0_09, // BTN2 BOOT = P1_01, WAKE0 = P0_15, // JP15 to select WAKE1 = P1_00, // JP8 (BTN1 jumper) to select WAKE2 = P0_13, // JP4 to select WAKE3 = P2_01, // JP15 to select // SPI Pins SPI0_SCLK = P0_00, SPI0_MOSI = P0_01, SPI0_MISO = P0_02, SPI0_CS0 = P0_03, SPI0_CS1 = P1_10, SPI0_CS2 = P2_08, SPI0_CS3 = P2_09, SPI1_SCLK = P1_06, SPI1_MOSI = P1_07, SPI1_MISO = P1_08, SPI1_CS0 = P1_09, SPI1_CS1 = P2_11, SPI1_CS2 = P2_02, SPI1_CS3 = P1_10, SPI2_SCLK = P1_02, SPI2_MOSI = P1_03, SPI2_MISO = P1_04, SPI2_CS0 = P1_05, SPI2_CS1 = P0_09, SPI2_CS2 = P2_10, SPI2_CS3 = P2_07, // ADC Pins ADC_VIN0 = P2_03, ADC_VIN1 = P2_04, ADC_VIN2 = P2_05, ADC_VIN3 = P2_06, ADC_VIN4 = P2_07, ADC_VIN5 = P2_08, ADC_VIN6 = P2_09, ADC_VIN7 = P2_10, // Arduino Headers D0 = P0_10, // UART0_TXD D1 = P0_11, // UART0_RXD D2 = P0_15, // INT_WAKE0 D3 = P0_13, // EXT_INT_WAKE2 D4 = P0_09, // EXT_SPI2_CS1 D5 = P2_01, // INT_WAKE3 or EXT_RTC1_SS1 via JP8 D6 = P1_11, // GPIO_27 D7 = P0_12, // GPIO_08 or GPIO_12 via JP7 D8 = P1_12, // GPIO_28 D9 = P1_14, // GPIO_30 D10 = SPI0_CS2, // P2_08 D11 = SPI0_MOSI, // P0_01 D12 = SPI0_MISO, // P0_02 D13 = SPI0_SCLK, // P0_00 I2C_SCL = P0_04, // I2C_SCL I2C_SDA = P0_05, // I2C_SDA A0 = P2_03, // ADC0 A1 = P2_04, // EXT_ADC1 A2 = P2_05, // EXT_ADC2 A3 = P2_06, // ADC3 A4 = P2_07, // SPI2_CS3 A5 = P2_10, // EXT_GPIO42 // Not connected NC = (int)0xFFFFFFFF } PinName; <</CODE>>
main.cpp
- Committer:
- APS_Lab
- Date:
- 2019-01-11
- Revision:
- 0:5868fc6c16b3
File content as of revision 0:5868fc6c16b3:
/* mbed Microcontroller Library
* Copyright (c) 2018 ARM Limited
* SPDX-License-Identifier: Apache-2.0
*/
#include "mbed.h"
#include "stats_report.h"
#include "ADXL362.h"
#include "math.h"
#define G_2 1.0
#define G_4 2.0
#define G_8 4.0
#define MODE_NORMAL 0
#define MODE_LOW_POWER 1
#define MODE_ULTRA_LOW_POWER 2
DigitalOut led1(LED1);
Serial PC(USBTX, USBRX);
char Buf[128];
char command[8];
char mode[8];
char val[8];
int f_val;
int set_mode(int m);
int set_freq(int v);
int set_grav(int v);
void set_start(void);
void set_stop(void);
static void clearDisplay(void);
static void drawCLI(ADXL362 *adxlCtrl, AccelTemp *getData);
volatile int f_run = 0;
volatile int f_wake = 0;
SPI *spi1;
ADXL362 *adxlCtrl;
AccelTemp GetData;
DigitalIn ADXL_WAKE(WAKE2);
// main() runs in its own thread in the OS
int main()
{
PC.baud(115200);
PC.printf("EV-COG-AD4050LZ Demo\n");
spi1 = new SPI(SPI1_MOSI, SPI1_MISO, SPI1_SCLK);
adxlCtrl = new ADXL362(&PC, spi1);
clearDisplay();
while (true) {
// Blink LED and wait 0.5 seconds
led1 = !led1;
wait_ms(500);
PC.scanf("%s", command);
if(strncmp(command, "set", 3) == 0)
{
PC.scanf("%s",mode);
if(strncmp(mode, "freq", 4) == 0)
{
PC.scanf("%s", val);
f_val = atoi(val);
set_freq(f_val);
}
else if(strncmp(mode, "mode", 4) == 0)
{
PC.scanf("%s", val);
f_val = atoi(val);
set_mode(f_val);
}
else if(strncmp(mode, "grav", 4) == 0)
{
PC.scanf("%s", val);
f_val = atoi(val);
set_grav(f_val);
}
else if(strncmp(mode, "wakeup", 6) == 0)
{
PC.printf("ADXL362 wakeup mode\n");
adxlCtrl->set_wakeupmode();
f_wake = 1;
PC.printf("ADXL362 wakeup waiting......\n");
while(f_wake)
{
if()
{
f_wake = 0;
PC.printf("ADXL362 Wake-up\n");
}
}
}else
{
PC.printf("Command Invalid\n");
}
}
else if(strncmp(command, "start", 5) == 0)
{
set_start();
while(f_run)
{
adxlCtrl->SensorRead(&GetData);
drawCLI(adxlCtrl, &GetData);
wait(0.5);
}
}
//else if(strncmp(command, "stop", 4) == 0)
//{
// set_stop();
//}
else
{
PC.printf("Command Usage\n");
PC.printf("Command : only 'set'\n");
PC.printf("Mode : 'freq' is ODR configuration\n");
PC.printf(" : ODR frequency from 12, 25, 50, 100, 200, 400Hz\n");
PC.printf("Mode : 'grav' is select gravity\n");
PC.printf(" : 0:2g 1:4g 2:8g\n");
PC.printf("Mode : 'mode' is power mode\n");
PC.printf(" : 0:Normal 1:Low Power 2:Ultra Low Power(freq is fixed at 100Hz)\n");
PC.printf("i.e. 'set mode 0'\n");
PC.printf("i.e. 'set freq 1000'\n");
PC.printf("i.e. 'start'\n");
}
// Following the main thread wait, report on the current system status
//sys_state.report_state();
}
}
int set_freq(int v)
{
if((v < 12) || (v > 400))
{
PC.printf("ODR Freqency Range is over/under. Please configure for 12-400 Hz.\n");
return 1;
}
else
{
PC.printf("Set Frequency %d Hz\n", v);
return 0;
}
}
int set_grav(int v)
{
switch(v)
{
case 0:
PC.printf("Set gravity 2g\n");
adxlCtrl->set_gravity(GRAVITY_2G);
break;
case 1:
PC.printf("Set gravity 4g\n");
adxlCtrl->set_gravity(GRAVITY_4G);
break;
case 2:
PC.printf("Set gravity 8g\n");
adxlCtrl->set_gravity(GRAVITY_8G);
break;
default:
PC.printf("Unknown Command\n");
break;
};
return 0;
}
int set_mode(int m)
{
switch(m)
{
case MODE_NORMAL:
PC.printf("Set Normal Mode\n");
adxlCtrl->set_powermode(POWER_CTL_PARAM_LOWNOISE_NORM);
break;
case MODE_LOW_POWER:
PC.printf("Set Low Power Mode\n");
adxlCtrl->set_powermode(POWER_CTL_PARAM_LOWNOISE_LOW);
break;
case MODE_ULTRA_LOW_POWER:
PC.printf("Set Ultra Low Power Mode\n");
adxlCtrl->set_powermode(POWER_CTL_PARAM_LOWNOISE_ULTRA);
break;
default:
PC.printf("Unknown Command\n");
break;
};
return 0;
}
void set_start(void)
{
f_run = 1;
adxlCtrl->start();
PC.printf("Start Accel\n");
}
void set_stop(void)
{
f_run = 0;
adxlCtrl->stop();
PC.printf("Stop Accel\n");
}
static void clearDisplay(void)
{
PC.printf("\033[2J");
PC.printf("\033[0;0H");
PC.printf("\033[0m\033[37m");
}
static void drawCLI(ADXL362 *adxlCtrl, AccelTemp *getData)
{
AccelTemp *min = adxlCtrl->GetMinInfo();
AccelTemp *max = adxlCtrl->GetMaxInfo();
AccelTemp *p;
float x, y, z, t;
PC.printf("\033[2J");
/* BLANK LINE */
PC.printf("\033[0m\033[33m\033[1m");
PC.printf("\033[2;1H");
PC.printf("\033[K");
PC.printf("ACCELEROMETERs");
PC.printf("\033[0m\033[37m");
PC.printf("\033[3;3H");
PC.printf("\033[K");
PC.printf("\033[3;10H-X---\033[3;20H-Y---\033[3;30H-Z---");
PC.printf("\033[0m\033[35m");
PC.printf("\033[4;3H");
PC.printf("\033[K");
p = min;
x = sin(adxlCtrl->ConvAccel(p->ax));
y = adxlCtrl->ConvAccel(p->ay);
z = adxlCtrl->ConvAccel(p->az);
PC.printf("min\033[4;10H%04.2f\033[4;20H%04.2f\033[4;30H%04.2f", x, y, z);
PC.printf("\033[0m\033[37m\033[1m");
PC.printf("\033[5;3H");
PC.printf("\033[K");
p = getData;
x = adxlCtrl->ConvAccel(p->ax);
y = adxlCtrl->ConvAccel(p->ay);
z = adxlCtrl->ConvAccel(p->az);
PC.printf("-->\033[5;10H%04.2f\033[5;20H%04.2f\033[5;30H%04.2f", x, y, z);
PC.printf("\033[0m\033[36m");
PC.printf("\033[6;3H");
PC.printf("\033[K");
p = max;
x = adxlCtrl->ConvAccel(p->ax);
y = adxlCtrl->ConvAccel(p->ay);
z = adxlCtrl->ConvAccel(p->az);
PC.printf("max\033[6;10H%04.2f\033[6;20H%04.2f\033[6;30H%04.2f", x, y, z);
/* BLANK LINE */
PC.printf("\033[0m\033[31m\033[1m");
PC.printf("\033[8;1H");
PC.printf("\033[K");
PC.printf("Temperature");
/* BLANK LINE */
PC.printf("\033[0m\033[35m");
PC.printf("\033[10;3H");
PC.printf("\033[K");
p = min;
t = adxlCtrl->ConvThermal(p->tm);
PC.printf("min\033[10;10H%04.2f", t);
PC.printf("\033[0m\033[37m\033[1m");
PC.printf("\033[11;3H");
PC.printf("\033[K");
p = getData;
t = adxlCtrl->ConvThermal(p->tm);
PC.printf("-->\033[11;10H%04.2f", t);
PC.printf("\033[0m\033[36m");
PC.printf("\033[12;3H");
PC.printf("\033[K");
p = max;
t = adxlCtrl->ConvThermal(p->tm);
PC.printf("max\033[12;10H%04.2f", t);
}