Renesas
Sample program for communicating with Fujitsuu IoT Platform using HTTP
Dependencies: AsciiFont GR-PEACH_video GraphicsFramework LCD_shield_config R_BSP USBHost_custom easy-connect-gr-peach mbed-http picojson BM1383GLV KX022 rohm-sensor-hal rohm-bh1745
Overview
This sample program shows how to send the cognitive data and sensing data gathered by Omron HVC-P2 and Rohm Sensor Shield respectively to IoT Platform managed by FUJITSU ( http://jp.fujitsu.com/solutions/cloud/k5/function/paas/iot-platform/ ).
Required Hardware
- GR-PEACH ( https://developer.mbed.org/platforms/Renesas-GR-PEACH/ )
- LCD Shield ( https://developer.mbed.org/teams/Renesas/Wiki/LCD-shield )
- HVC-P2 ( Human Vision Components B5T-007001 ) ( https://plus-sensin.omron.com/product/B5T-007001/ )
- SensorShield-EVK-001 ( Rohm Sensor Evaluation Kit ) ( http://www.rohm.com/web/global/sensor-shield-support )
Application Setup
- Configure the connection type. For details, please refer to the following link:
https://developer.mbed.org/teams/Renesas/code/GR-PEACH_IoT_Platform_HTTP_sample/wiki/Connection-Type - Configure Ethernet settings. For details, please refer to the following link:
https://developer.mbed.org/teams/Renesas/code/GR-PEACH_IoT_Platform_HTTP_sample/wiki/Ethernet-settings - Set up the Access Code of resource where the gathered data would be stored. For details on Access Code, please refer to the following links:
https://iot-docs.jp-east-1.paas.cloud.global.fujitsu.com/en/manual/userguide_en.pdf
https://iot-docs.jp-east-1.paas.cloud.global.fujitsu.com/en/manual/apireference_en.pdf
https://iot-docs.jp-east-1.paas.cloud.global.fujitsu.com/en/manual/portalmanual_en.pdf
- Set up URI for the resource where the gathered data would be stored. For details, please refer to the following link:
https://iot-docs.jp-east-1.paas.cloud.global.fujitsu.com/en/manual/userguide_en.pdf
https://iot-docs.jp-east-1.paas.cloud.global.fujitsu.com/en/manual/apireference_en.pdf
Building Example
- Import this sample program onto mbed Compiler
- Configure the program in accordance with the description of Application Setup above
- Compile the sample program
- Plug the Ethernet cable into GR-PEACH if you would like Ethernet mode
- Plug micro-USB cable into the OpenSDA port which lies on the next to the RESET button
- Copy the binary previously downloaded to your PC to GR-PEACH in order to flash this program. When the copy is successfully completed, the drive named MBED should be re-mounted automatically
- Press the RESET button on the board to run the sample application
Data Format sent to IoT Platform
In this sample program, the cognitive data and sensing data are serialized into the following JSON format using picojson (https://developer.mbed.org/users/mimil/code/picojson/):
- Face detection data
{
"RecordType": "HVC-P2(face)",
"id": "<GR-PEACH ID>-<Sensor ID>",
"Age": xxx,
"FaceRectangle": {
"Height": xxx,
"Left": xxx,
"Top": xxx,
"Width": xxx
},
"Gender": xxx,
"Scores": {
"Anger": xxx,
"Happiness": xxx,
"Neutral": xxx,
"Sadness": xxx,
"Surprise": xxx
}
}
- Body detection data
{
"RecodeType": "HVC-P2(body)",
"id": "<GR-PEACH ID>-<Sensor ID>",
"BodyRectangle": {
"Height": xxx,
"Left": xxx,
"Top": xxx,
"Width": xxx
}
}
- Accelerometer data
{
"RecodeType": "Accelerometer",
"id": "<GR-PEACH ID>-<Sensor ID>",
"data": [ acceleratoin(x-direction), acceleration(y-direction), acceleration(z-direction), null, null, null ]
}
Note that data[0], data[1] and data[2] are filled with the acceleration data in x, y and z direction respectively, and the remaining elements are filled with null.
- Atmosphere data
{
"RecodeType": "Atmosphere",
"id": "<GR-PEACH ID>-<Sensor ID>",
"data": [ atmosphere data, null, null, null, null, null ]
}
Note that data[0] is filled with atmosphere data, and the remaining elements are filled with null.
- Color sensor data
{
"RecodeType": "Color",
"id": "<GR-PEACH ID>-<Sensor ID>",
"data": [ Red, Green, Blue, Alpha, null, null]
}
Note that data[0], data[1], data[2] and data[3] are filled with Red, Green, Blue and Alpha elements of color respectively, and the remaining elements are filled with null.
- Temperature data
{
"RecodeType": "Temperature",
"id": "<GR-PEACH ID>-<Sensor ID>",
"data": [ Temperature, null, null, null, null, null ]
}
Note that data[0] is filled with temperature data, the remaining elements are filled with null.
- Geomagnetism
{
"RecodeType": "Geomagnetism",
"id": "<GR-PEACH ID>-<Sensor ID>",
"data": [ geomagnetism(x-direction), geomagnetism(y-direction), geomagnetism(z-direction), null, null, null]
}
Note that data[0], data[1] and data[2] are filled with the geomagnetism data in x, y and z direction respectively, and the remaining elements are filled with null.
sensor_shield/BM1422AGMV/BM1422AGMV.cpp
- Committer:
- Osamu Nakamura
- Date:
- 2018-04-12
- Revision:
- 7:9ae73f85dc04
- Parent:
- 6:ff12fc4d75f0
File content as of revision 7:9ae73f85dc04:
/* Copyright (c) 2015 ARM Ltd., MIT License
*
* Permission is hereby granted, free of charge, to any person obtaining a copy of this software
* and associated documentation files (the "Software"), to deal in the Software without
* restriction, including without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all copies or
* substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING
* BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
*/
#include "mbed.h"
#include "BM1422AGMV.h"
BM1422AGMV::BM1422AGMV(PinName sda, PinName scl, int addr) : m_i2c(sda, scl), m_addr(addr)
{
initialize();
}
BM1422AGMV::BM1422AGMV(I2C &i2c_obj, int addr) : m_i2c(i2c_obj), m_addr(addr)
{
initialize();
}
BM1422AGMV::~BM1422AGMV()
{
/* do nothing */
}
void BM1422AGMV::initialize(void)
{
uint8_t reg;
uint8_t buf[3];
_drdy_flg = 0;
DEBUG_PRINT("BM1422AGMV init started\n\r");
readRegs(BM1422AGMV_WIA, ®, 1);
if ( reg != BM1422AGMV_WIA_VAL) {
DEBUG_PRINT("BM1422AGMV initialization error. (WAI %d, not %d)\n\r", buf, BM1422AGMV_WIA);
DEBUG_PRINT("Trying to config anyway, in case there is some compatible sensor connected.\n\r");
}
// Step1
buf[0] = BM1422AGMV_CNTL1;
buf[1] = BM1422AGMV_CNTL1_VAL;
writeRegs(buf, 2);
// Check 12bit or 14bit
reg = (BM1422AGMV_CNTL1_VAL & BM1422AGMV_CNTL1_OUT_BIT);
if (reg == BM1422AGMV_CNTL1_OUT_BIT) {
_sens = BM1422AGMV_14BIT_SENS;
} else {
_sens = BM1422AGMV_12BIT_SENS;
}
wait(1);
buf[0] = BM1422AGMV_CNTL4;
buf[1] = (BM1422AGMV_CNTL4_VAL >> 8) & 0xFF;
buf[2] = (BM1422AGMV_CNTL4_VAL & 0xFF);
writeRegs(buf, 3);
// Step2
buf[0] = BM1422AGMV_CNTL2;
buf[1] = BM1422AGMV_CNTL2_VAL;
writeRegs(buf, 2);
// Step3
// Option
buf[0] = BM1422AGMV_AVE_A;
buf[1] = BM1422AGMV_AVE_A_VAL;
writeRegs(buf, 2);
}
void BM1422AGMV::get_rawval(unsigned char *data)
{
uint8_t reg;
uint8_t buf[2];
// Step 4
buf[0] = BM1422AGMV_CNTL3;
buf[1] = BM1422AGMV_CNTL3_VAL;
writeRegs(buf, 2);
while(1) {
readRegs(BM1422AGMV_STA1, ®, 1);
if ( (reg>>6) == 1) {
break;
}
wait_ms(100);
}
readRegs(BM1422AGMV_DATAX, data, 6);
}
void BM1422AGMV::get_val(float *data)
{
uint8_t val[6];
int16_t mag[3];
get_rawval(val);
mag[0] = ((int16_t)val[1] << 8) | (int16_t)(val[0]);
mag[1] = ((int16_t)val[3] << 8) | (int16_t)(val[2]);
mag[2] = ((int16_t)val[5] << 8) | (int16_t)(val[4]);
convert_uT(mag, data);
}
void BM1422AGMV::convert_uT(int16_t *rawdata, float *data)
{
// LSB to uT
data[0] = (float)rawdata[0] / _sens;
data[1] = (float)rawdata[1] / _sens;
data[2] = (float)rawdata[2] / _sens;
}
void BM1422AGMV::set_drdy_flg(void)
{
_drdy_flg = 1;
}
void BM1422AGMV::readRegs(int addr, uint8_t * data, int len)
{
int read_nok;
char t[1] = {addr};
m_i2c.write(m_addr, t, 1, true);
read_nok = m_i2c.read(m_addr, (char *)data, len);
if (read_nok){
DEBUG_PRINT("Read fail\n\r");
}
}
void BM1422AGMV::writeRegs(uint8_t * data, int len)
{
m_i2c.write(m_addr, (char *)data, len);
}