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2jciebu01: put new sources in right location

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Signed-off-by: Mihai Tudor Panu <mihai.tudor.panu@intel.com>
This commit is contained in:
Mihai Tudor Panu 2019-04-04 16:52:01 -07:00
parent e0be90589b
commit b08eef0197
16 changed files with 2710 additions and 2714 deletions
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2
Omron_2jcie-bu01_ble/upm/src/CMakeLists.txt
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@ -1,2 +0,0 @@
add_subdirectory(om2jciebu-ble)
file(COPY 2jciebu01.hpp DESTINATION /usr/local/include/)

2
Omron_2jcie-bu01_usb/upm/src/CMakeLists.txt
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@ -1,2 +0,0 @@
add_subdirectory(2jciebu01-usb)
file(COPY 2jciebu01.hpp DESTINATION /usr/local/include/)

1078
Omron_2jcie-bu01_ble/upm/examples/c++/omron2jciebu01_ble.cxx → examples/c++/2jciebu01-ble.cxx
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File diff suppressed because it is too large Load Diff

830
Omron_2jcie-bu01_usb/upm/examples/c++/omron2jciebu01_usb.cxx → examples/c++/2jciebu01-usb.cxx
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@ -1,415 +1,415 @@
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/* standard headers */
#include <iostream>
#include <signal.h>
#include <stdlib.h>
#include <unistd.h>
/* omron sensor headers */
#include "2jciebu01_usb.hpp"
using namespace std;
using namespace upm;
volatile sig_atomic_t flag = 1;
#define PREVIOUS_MENU_CHOICE 10
upm::OM2JCIEBU_UART::om2jciebuData_t om2jciebuSensorData;
void
sig_handler(int signum)
{
if(signum == SIGABRT) { //check for Abort signal
std::cout << "Exiting..." << std::endl;
}
if(signum == SIGINT) { //check for Interrupt signal
std::cout << "Exiting..." << std::endl;
flag = 0;
}
}
void getSensorData(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
uint16_t parameterChoice = 0;
int displayDelay = 0;
bool seconds_validate = false;
uint16_t sensorParamData = 0;
uint32_t pressureData = 0;
while(true) {
printf("************************************************************\r\n");
printf("Please select sensor attribute for display\r\n");
printf("0) All parameter\r\n");
printf("1) Temperature data\r\n");
printf("2) Relative humidity data\r\n");
printf("3) Ambient light data\r\n");
printf("4) Barometric pressure data\r\n");
printf("5) Sound noise data\r\n");
printf("6) eTVOC data\r\n");
printf("7) eCO2 data\r\n");
printf("8) Discomfort index data\r\n");
printf("9) Heat stroke data\r\n");
printf("10) Return to main menu\r\n");
printf("Note :: Press Ctrl+C for sensor attribute display menu\r\n");
printf("************************************************************\r\n");
while(!(std::cin >> parameterChoice)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
if(parameterChoice >= OM2JCIEBU_UART::ALL_PARAM && parameterChoice <= OM2JCIEBU_UART::HEAT_STROKE) {
flag = 1;
printf("Please enter time interval (in Seconds), for display sensor data\r\n");
while(!seconds_validate) { //validate user input values
cin >> displayDelay;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (displayDelay >= 1 && displayDelay <= 10)) {
seconds_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an second between 1 to 10!" << endl;
}
}
while(flag) {
switch(parameterChoice) {
case OM2JCIEBU_UART::ALL_PARAM:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ALL_PARAM, &om2jciebuSensorData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Sensor Attribute Values ***************\r\n");
printf("Sequence Number :: %d \r\n", om2jciebuSensorData.sequence_number);
printf("Temperature :: %d degC\r\n", om2jciebuSensorData.temperature);
printf("Relative humidity :: %d RH\r\n", om2jciebuSensorData.relative_humidity);
printf("Ambient light :: %d lx\r\n", om2jciebuSensorData.ambient_light);
printf("Barometric pressure :: %d hPa\r\n", om2jciebuSensorData.pressure);
printf("Sound noise :: %d dB\r\n", om2jciebuSensorData.noise);
printf("eTVOC :: %d ppb\r\n", om2jciebuSensorData.eTVOC);
printf("eCO2 :: %d ppm\r\n", om2jciebuSensorData.eCO2);
printf("Discomfort index :: %d \r\n", om2jciebuSensorData.discomfort_index);
printf("Heat stroke :: %d degC\r\n", om2jciebuSensorData.heat_stroke);
printf("**********************************************************\r\n");
memset(&om2jciebuSensorData, 0, sizeof(om2jciebuSensorData));
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::TEMP:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::TEMP, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Temperature Attribute Values ***************\r\n");
printf("Temperature :: %d degC\r\n", sensorParamData);
printf("************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::HUMIDITY:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::HUMIDITY, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Relative humidity Attribute Values ***************\r\n");
printf("Relative humidity :: %d RH\r\n", sensorParamData);
printf("******************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::AMBIENT_LIGHT:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::AMBIENT_LIGHT, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Ambient light Attribute Values ***************\r\n");
printf("Ambient light :: %d lx\r\n", sensorParamData);
printf("**************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::PRESSURE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::PRESSURE, &pressureData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Barometric pressure Attribute Values ***************\r\n");
printf("Barometric pressure :: %d hPa\r\n", pressureData);
printf("********************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::NOISE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::NOISE, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Sound noise Attribute Values ***************\r\n");
printf("Sound noise :: %d dB\r\n", sensorParamData);
printf("************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::ETVOC:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ETVOC, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eTVOC Attribute Values ***************\r\n");
printf("eTVOC :: %d ppb\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::ECO2:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ECO2, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("eCO2 :: %d ppm\r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::DISCOMFORT_INDEX:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::DISCOMFORT_INDEX, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("Discomfort index :: %d \r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::HEAT_STROKE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::HEAT_STROKE, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("Heat stroke :: %d degC\r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
}
printf("\r\n");
p_om2jcieuart->delay(displayDelay);
}
} else if(parameterChoice == PREVIOUS_MENU_CHOICE) {
break;
} else {
printf("Invalid choice\r\n");
}
seconds_validate = false;
}
}
void configureLEDSetting(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
int led_choice = 0;
bool red_scale_validate = false, green_scale_validate = false, blue_scale_validate = false;
unsigned short int red_scale = 0, green_scale = 0, blue_scale = 0;
printf("************** Sensor LED Configuration ***************\r\n");
printf("Please select a operation for LED\r\n");
printf("0) Normally OFF\r\n");
printf("1) Normally ON\r\n");
printf("2) Temperature value scales\r\n");
printf("3) Relative humidity value scales\r\n");
printf("4) Ambient light value scales\r\n");
printf("5) Barometric pressure value scales\r\n");
printf("6) Sound noise value scales\r\n");
printf("7) eTVOC value scales\r\n");
printf("8) SI vale scales\r\n");
printf("9) PGA value scales\r\n");
printf("**********************************************************\r\n");
while(!(std::cin >> led_choice)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
if(led_choice == OM2JCIEBU_UART::NORMALLY_ON) {
printf("Please Select a LED color scale\r\n");
printf("Please enter Red Color scale (scale range 0 to 255)\r\n");
while(!red_scale_validate) {
cin >> red_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (red_scale >= 0 && red_scale <= 255)) {
red_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an red color scale between 0 and 255!" << endl;
}
}
printf("Please enter Green Color scale(scale range 0 to 255)\r\n");
while(!green_scale_validate) {
cin >> green_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (green_scale >= 0 && green_scale <= 255)) {
green_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an green color scale between 0 and 255!" << endl;
}
}
printf("Please enter Blue Color scale(scale range 0 to 255)\r\n");
while(!blue_scale_validate) {
cin >> blue_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (blue_scale >= 0 && blue_scale <= 255)) {
blue_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an blue color scale between 0 and 255!" << endl;
}
}
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NORMALLY_ON, red_scale, green_scale, blue_scale);
} else {
switch(led_choice) {
case OM2JCIEBU_UART::NORMALLY_OFF:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NORMALLY_OFF, 0, 0, 0);
break;
case OM2JCIEBU_UART::TEMP_SACLE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::TEMP_SACLE, 0, 0, 0);
break;
case OM2JCIEBU_UART::HUMIDITY_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::HUMIDITY_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::AMBIENT_LIGHT_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::AMBIENT_LIGHT_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::PRESSURE_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::PRESSURE_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::NOISE_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NOISE_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::ETVOC_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::ETVOC_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::SI_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::SI_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::PGA_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::PGA_SCALE, 0, 0, 0);
break;
default:
std::cout << "Wrong LED scale choice please try again" << std::endl;
}
}
}
void configureAdvInterval(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
bool millisecond_validate = false;
uint16_t millisecond = 0;
int advertising_mode = 0;
printf("************** Sensor Advertise Configuration ***************\r\n");
printf("Please enter time interval (in Milliseconds), for changing Advertise interval, between 100 to 10240 milliseconds\r\n");
while(!millisecond_validate) {//validate millisecond
cin >> millisecond;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (millisecond >= 100 && millisecond <= 10240)) {
millisecond_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an milisecond between 100 and 10240!" << endl;
}
}
printf("Please select an Advertise mode with the selected Advertise interval \r\n");
printf("1) Sensor data\r\n");
printf("2) Calculation data\r\n");
printf("3) Sensor data and Calculation data\r\n");
printf("4) Sensor flag and Calculation flag\r\n");
printf("5) Serial number\r\n");
while(!(std::cin >> advertising_mode)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
switch(advertising_mode) {
case OM2JCIEBU_UART::SENSOR_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::SENSOR_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_SENSOR_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_SENSOR_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_SENSOR_FLAG:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_SENSOR_FLAG);
break;
case OM2JCIEBU_UART::SERIAL_NUMBER:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::SERIAL_NUMBER);
break;
default:
std::cout << "Invalid choice\n";
}
printf("**************************************************************\r\n");
}
int
main(int argc, char *argv[])
{
char *dev_path;
int operation_choice = 0;
if(argc <= 1) {
std::cout << "usage ./a.out /dev/ttyUSB*" << std::endl;
return 0;
}
signal(SIGABRT, sig_handler);
signal(SIGINT, sig_handler);
upm::OM2JCIEBU_UART om2jciebu_uart(argv[1], 115200);
om2jciebu_uart.setMode(8, mraa::UART_PARITY_NONE, 1);
om2jciebu_uart.setFlowControl(false, false);
while(true) {
std::cout << "*************************************************************" << std::endl;
std::cout << "Please choose one option for Omron sensor operation" << std::endl;
std::cout << "1) Display Sensor attriutes" << std::endl;
std::cout << "2) Configure LED setting " << std::endl;
std::cout << "3) Configure advertise setting" << std::endl;
std::cout << "4) Exit" << std::endl;
std::cout << "*************************************************************" << std::endl;
while(!(std::cin >> operation_choice)) { //validate operation choice from user input
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
switch(operation_choice) {
case 1:
getSensorData(&om2jciebu_uart);
break;
case 2:
configureLEDSetting(&om2jciebu_uart);
break;
case 3:
configureAdvInterval(&om2jciebu_uart);
break;
case 4:
std::cout << "Application Exited" << std::endl;
exit(0);
break;
default:
std::cout << "Invalid choice" << std::endl;
}
}
}
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/* standard headers */
#include <iostream>
#include <signal.h>
#include <stdlib.h>
#include <unistd.h>
/* omron sensor headers */
#include "2jciebu01_usb.hpp"
using namespace std;
using namespace upm;
volatile sig_atomic_t flag = 1;
#define PREVIOUS_MENU_CHOICE 10
upm::OM2JCIEBU_UART::om2jciebuData_t om2jciebuSensorData;
void
sig_handler(int signum)
{
if(signum == SIGABRT) { //check for Abort signal
std::cout << "Exiting..." << std::endl;
}
if(signum == SIGINT) { //check for Interrupt signal
std::cout << "Exiting..." << std::endl;
flag = 0;
}
}
void getSensorData(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
uint16_t parameterChoice = 0;
int displayDelay = 0;
bool seconds_validate = false;
uint16_t sensorParamData = 0;
uint32_t pressureData = 0;
while(true) {
printf("************************************************************\r\n");
printf("Please select sensor attribute for display\r\n");
printf("0) All parameter\r\n");
printf("1) Temperature data\r\n");
printf("2) Relative humidity data\r\n");
printf("3) Ambient light data\r\n");
printf("4) Barometric pressure data\r\n");
printf("5) Sound noise data\r\n");
printf("6) eTVOC data\r\n");
printf("7) eCO2 data\r\n");
printf("8) Discomfort index data\r\n");
printf("9) Heat stroke data\r\n");
printf("10) Return to main menu\r\n");
printf("Note :: Press Ctrl+C for sensor attribute display menu\r\n");
printf("************************************************************\r\n");
while(!(std::cin >> parameterChoice)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
if(parameterChoice >= OM2JCIEBU_UART::ALL_PARAM && parameterChoice <= OM2JCIEBU_UART::HEAT_STROKE) {
flag = 1;
printf("Please enter time interval (in Seconds), for display sensor data\r\n");
while(!seconds_validate) { //validate user input values
cin >> displayDelay;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (displayDelay >= 1 && displayDelay <= 10)) {
seconds_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an second between 1 to 10!" << endl;
}
}
while(flag) {
switch(parameterChoice) {
case OM2JCIEBU_UART::ALL_PARAM:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ALL_PARAM, &om2jciebuSensorData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Sensor Attribute Values ***************\r\n");
printf("Sequence Number :: %d \r\n", om2jciebuSensorData.sequence_number);
printf("Temperature :: %d degC\r\n", om2jciebuSensorData.temperature);
printf("Relative humidity :: %d RH\r\n", om2jciebuSensorData.relative_humidity);
printf("Ambient light :: %d lx\r\n", om2jciebuSensorData.ambient_light);
printf("Barometric pressure :: %d hPa\r\n", om2jciebuSensorData.pressure);
printf("Sound noise :: %d dB\r\n", om2jciebuSensorData.noise);
printf("eTVOC :: %d ppb\r\n", om2jciebuSensorData.eTVOC);
printf("eCO2 :: %d ppm\r\n", om2jciebuSensorData.eCO2);
printf("Discomfort index :: %d \r\n", om2jciebuSensorData.discomfort_index);
printf("Heat stroke :: %d degC\r\n", om2jciebuSensorData.heat_stroke);
printf("**********************************************************\r\n");
memset(&om2jciebuSensorData, 0, sizeof(om2jciebuSensorData));
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::TEMP:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::TEMP, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Temperature Attribute Values ***************\r\n");
printf("Temperature :: %d degC\r\n", sensorParamData);
printf("************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::HUMIDITY:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::HUMIDITY, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Relative humidity Attribute Values ***************\r\n");
printf("Relative humidity :: %d RH\r\n", sensorParamData);
printf("******************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::AMBIENT_LIGHT:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::AMBIENT_LIGHT, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Ambient light Attribute Values ***************\r\n");
printf("Ambient light :: %d lx\r\n", sensorParamData);
printf("**************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::PRESSURE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::PRESSURE, &pressureData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Barometric pressure Attribute Values ***************\r\n");
printf("Barometric pressure :: %d hPa\r\n", pressureData);
printf("********************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::NOISE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::NOISE, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** Sound noise Attribute Values ***************\r\n");
printf("Sound noise :: %d dB\r\n", sensorParamData);
printf("************************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::ETVOC:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ETVOC, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eTVOC Attribute Values ***************\r\n");
printf("eTVOC :: %d ppb\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::ECO2:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::ECO2, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("eCO2 :: %d ppm\r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::DISCOMFORT_INDEX:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::DISCOMFORT_INDEX, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("Discomfort index :: %d \r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
case OM2JCIEBU_UART::HEAT_STROKE:
if(p_om2jcieuart->getSensorData(OM2JCIEBU_UART::HEAT_STROKE, &sensorParamData) == OM2JCIEBU_UART::SUCCESS) {
printf("************** eCO2 Attribute Values ***************\r\n");
printf("Heat stroke :: %d degC\r\n\r\n", sensorParamData);
printf("******************************************************\r\n");
} else {
flag = 0;
}
break;
}
printf("\r\n");
p_om2jcieuart->delay(displayDelay);
}
} else if(parameterChoice == PREVIOUS_MENU_CHOICE) {
break;
} else {
printf("Invalid choice\r\n");
}
seconds_validate = false;
}
}
void configureLEDSetting(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
int led_choice = 0;
bool red_scale_validate = false, green_scale_validate = false, blue_scale_validate = false;
unsigned short int red_scale = 0, green_scale = 0, blue_scale = 0;
printf("************** Sensor LED Configuration ***************\r\n");
printf("Please select a operation for LED\r\n");
printf("0) Normally OFF\r\n");
printf("1) Normally ON\r\n");
printf("2) Temperature value scales\r\n");
printf("3) Relative humidity value scales\r\n");
printf("4) Ambient light value scales\r\n");
printf("5) Barometric pressure value scales\r\n");
printf("6) Sound noise value scales\r\n");
printf("7) eTVOC value scales\r\n");
printf("8) SI vale scales\r\n");
printf("9) PGA value scales\r\n");
printf("**********************************************************\r\n");
while(!(std::cin >> led_choice)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
if(led_choice == OM2JCIEBU_UART::NORMALLY_ON) {
printf("Please Select a LED color scale\r\n");
printf("Please enter Red Color scale (scale range 0 to 255)\r\n");
while(!red_scale_validate) {
cin >> red_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (red_scale >= 0 && red_scale <= 255)) {
red_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an red color scale between 0 and 255!" << endl;
}
}
printf("Please enter Green Color scale(scale range 0 to 255)\r\n");
while(!green_scale_validate) {
cin >> green_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (green_scale >= 0 && green_scale <= 255)) {
green_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an green color scale between 0 and 255!" << endl;
}
}
printf("Please enter Blue Color scale(scale range 0 to 255)\r\n");
while(!blue_scale_validate) {
cin >> blue_scale;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (blue_scale >= 0 && blue_scale <= 255)) {
blue_scale_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an blue color scale between 0 and 255!" << endl;
}
}
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NORMALLY_ON, red_scale, green_scale, blue_scale);
} else {
switch(led_choice) {
case OM2JCIEBU_UART::NORMALLY_OFF:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NORMALLY_OFF, 0, 0, 0);
break;
case OM2JCIEBU_UART::TEMP_SACLE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::TEMP_SACLE, 0, 0, 0);
break;
case OM2JCIEBU_UART::HUMIDITY_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::HUMIDITY_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::AMBIENT_LIGHT_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::AMBIENT_LIGHT_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::PRESSURE_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::PRESSURE_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::NOISE_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::NOISE_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::ETVOC_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::ETVOC_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::SI_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::SI_SCALE, 0, 0, 0);
break;
case OM2JCIEBU_UART::PGA_SCALE:
p_om2jcieuart->configureSensorLedState(OM2JCIEBU_UART::PGA_SCALE, 0, 0, 0);
break;
default:
std::cout << "Wrong LED scale choice please try again" << std::endl;
}
}
}
void configureAdvInterval(OM2JCIEBU_UART *p_om2jcieuart)
{
if(p_om2jcieuart == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
bool millisecond_validate = false;
uint16_t millisecond = 0;
int advertising_mode = 0;
printf("************** Sensor Advertise Configuration ***************\r\n");
printf("Please enter time interval (in Milliseconds), for changing Advertise interval, between 100 to 10240 milliseconds\r\n");
while(!millisecond_validate) {//validate millisecond
cin >> millisecond;
if(!cin.fail() && (cin.peek() == EOF || cin.peek() == '\n') && (millisecond >= 100 && millisecond <= 10240)) {
millisecond_validate = true;
} else {
cin.clear();
cin.ignore();
cout << "Error, enter an milisecond between 100 and 10240!" << endl;
}
}
printf("Please select an Advertise mode with the selected Advertise interval \r\n");
printf("1) Sensor data\r\n");
printf("2) Calculation data\r\n");
printf("3) Sensor data and Calculation data\r\n");
printf("4) Sensor flag and Calculation flag\r\n");
printf("5) Serial number\r\n");
while(!(std::cin >> advertising_mode)) {
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
switch(advertising_mode) {
case OM2JCIEBU_UART::SENSOR_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::SENSOR_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_SENSOR_DATA:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_SENSOR_DATA);
break;
case OM2JCIEBU_UART::ACCELERATION_SENSOR_FLAG:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::ACCELERATION_SENSOR_FLAG);
break;
case OM2JCIEBU_UART::SERIAL_NUMBER:
p_om2jcieuart->configureSensorAdvSetting(millisecond, OM2JCIEBU_UART::SERIAL_NUMBER);
break;
default:
std::cout << "Invalid choice\n";
}
printf("**************************************************************\r\n");
}
int
main(int argc, char *argv[])
{
char *dev_path;
int operation_choice = 0;
if(argc <= 1) {
std::cout << "usage ./a.out /dev/ttyUSB*" << std::endl;
return 0;
}
signal(SIGABRT, sig_handler);
signal(SIGINT, sig_handler);
upm::OM2JCIEBU_UART om2jciebu_uart(argv[1], 115200);
om2jciebu_uart.setMode(8, mraa::UART_PARITY_NONE, 1);
om2jciebu_uart.setFlowControl(false, false);
while(true) {
std::cout << "*************************************************************" << std::endl;
std::cout << "Please choose one option for Omron sensor operation" << std::endl;
std::cout << "1) Display Sensor attriutes" << std::endl;
std::cout << "2) Configure LED setting " << std::endl;
std::cout << "3) Configure advertise setting" << std::endl;
std::cout << "4) Exit" << std::endl;
std::cout << "*************************************************************" << std::endl;
while(!(std::cin >> operation_choice)) { //validate operation choice from user input
std::cin.clear(); //clear bad input flag
std::cin.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); //discard input
std::cout << "Invalid input; please re-enter.\n";
}
switch(operation_choice) {
case 1:
getSensorData(&om2jciebu_uart);
break;
case 2:
configureLEDSetting(&om2jciebu_uart);
break;
case 3:
configureAdvInterval(&om2jciebu_uart);
break;
case 4:
std::cout << "Application Exited" << std::endl;
exit(0);
break;
default:
std::cout << "Invalid choice" << std::endl;
}
}
}

1000
Omron_2jcie-bu01_ble/upm/src/2jciebu-ble/2jciebu01_ble.cxx → src/2jciebu01-ble/2jciebu01_ble.cxx
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File diff suppressed because it is too large Load Diff

460
Omron_2jcie-bu01_ble/upm/src/2jciebu-ble/2jciebu01_ble.hpp → src/2jciebu01-ble/2jciebu01_ble.hpp
View File

@ -1,230 +1,230 @@
/*
*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include <tinyb.hpp>
#include <iostream>
#include <string>
#include <stdexcept>
#include <vector>
#include <thread>
#include <atomic>
#include <csignal>
#include "../2jciebu01.hpp"
/*MACROS and enum */
#define OM2JCIEBU_BLE_DISCOVERY_RETRY 15
#define OM2JCIEBU_BLE_LED_AND_ADV_CONFIGUARTION_SERVICE "ab705110-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_BLE_LIVE_SENSOR_DATA_SERVICE "ab705010-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_BLE_COM_ID_INDEX 0x00
#define OM2JCIEBU_BLE_DATA_TYPE_INDEX 0x02
#define VERIFY_PACKET 0
#define DEBUG_LOG 0
#define MAX_UUID_SIZE 64
#define MAX_SENSOR_DATA_SIZE 64
/*=========================================================================*/
namespace upm
{
/**
* @brief 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01_ble
* @ingroup Omron USB type
*/
/**
* @library libupm-2jciebu01_ble
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con ble
*
* @brief API for the Omron USB type environment Sensor Module using BLE interface
*
* It is connected via a BLE Interface
*
* @snippet 2jciebu01_ble.cxx Interesting
*/
class OM2JCIEBU_BLE : public OM2JCIEBU
{
public :
/**
* OM2JCIEBU_BLE Constructor, takes the device address as
* an argument
*
* @param device MAC address of Omron Environment Sensor
*/
OM2JCIEBU_BLE(std::string ble_address);
/**
* Get discovery service from Connetced BLE device
*
* @param attribute_name attribute name of sensor
* @return OM2JCIEBU_ERROR_T
*/
OM2JCIEBU_ERROR_T getDiscoveredServices(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name);
/**
* Get omron sensor live data as per request uisng 0x5012 UUID
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Get omron sensor live data based on advertise payload
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getAdvSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
void configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue);
/**
* Set Advertise interval setting of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode);
/**
* Disconnect BLE Device
*
* @return Return success or Failure
*
*/
bool removeBleDevice();
private:
BluetoothManager *bleManager = nullptr;
BluetoothDevice *bleSensorTag = nullptr;
BluetoothGattCharacteristic *bleSensorChar = nullptr;
BluetoothGattService *bleService = nullptr;
om2jciebuData_t om2jciebuData_ble;
std::string bleMACaddress;
bool is_BleConnected = false;
/**
*connect BLE Device
*
* @param device_address BLE deivce adddress
*
* @return Return success or Failure
*/
bool connectBleDevice(std::string ble_address);
/**
* Start BLE Discovery
*
* @return Return success or Failure
*/
bool startBleDiscovery();
/**
* Stop BLE Discovery
*
* @return Return success or Failure
*/
bool stopBleDiscovery();
/**
* Get sensor data from global struct.
*
* @param attribute_name attribute_name of sensor data
* @param attributeValue Data of attirbute
*/
void getSensorAttribute(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue);
/**
* Verifies the packet header and indicates its valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len);
/**
* Calculate and parse advertise sensor data and store into
* structure
*
* @param data Packet
*
*/
void parseAdvSensorData(uint8_t *data);
/**
* Calculate and parse sensor data and store into
* structure
*
* @param data Packet
*
*/
void parseSensorData(uint8_t *data);
/**
* Write packet over BLE
*
* @param attribute_name attribute_name of sensor
* @param arg_value arg value for write a data over BLE
*
* @return Return success or Failure
*/
bool writePacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, const std::vector<unsigned char> &arg_value);
};
}
/*
*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include <tinyb.hpp>
#include <iostream>
#include <string>
#include <stdexcept>
#include <vector>
#include <thread>
#include <atomic>
#include <csignal>
#include "../2jciebu01.hpp"
/*MACROS and enum */
#define OM2JCIEBU_BLE_DISCOVERY_RETRY 15
#define OM2JCIEBU_BLE_LED_AND_ADV_CONFIGUARTION_SERVICE "ab705110-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_BLE_LIVE_SENSOR_DATA_SERVICE "ab705010-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_BLE_COM_ID_INDEX 0x00
#define OM2JCIEBU_BLE_DATA_TYPE_INDEX 0x02
#define VERIFY_PACKET 0
#define DEBUG_LOG 0
#define MAX_UUID_SIZE 64
#define MAX_SENSOR_DATA_SIZE 64
/*=========================================================================*/
namespace upm
{
/**
* @brief 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01_ble
* @ingroup Omron USB type
*/
/**
* @library libupm-2jciebu01_ble
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con ble
*
* @brief API for the Omron USB type environment Sensor Module using BLE interface
*
* It is connected via a BLE Interface
*
* @snippet 2jciebu01_ble.cxx Interesting
*/
class OM2JCIEBU_BLE : public OM2JCIEBU
{
public :
/**
* OM2JCIEBU_BLE Constructor, takes the device address as
* an argument
*
* @param device MAC address of Omron Environment Sensor
*/
OM2JCIEBU_BLE(std::string ble_address);
/**
* Get discovery service from Connetced BLE device
*
* @param attribute_name attribute name of sensor
* @return OM2JCIEBU_ERROR_T
*/
OM2JCIEBU_ERROR_T getDiscoveredServices(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name);
/**
* Get omron sensor live data as per request uisng 0x5012 UUID
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Get omron sensor live data based on advertise payload
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getAdvSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
void configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue);
/**
* Set Advertise interval setting of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode);
/**
* Disconnect BLE Device
*
* @return Return success or Failure
*
*/
bool removeBleDevice();
private:
BluetoothManager *bleManager = nullptr;
BluetoothDevice *bleSensorTag = nullptr;
BluetoothGattCharacteristic *bleSensorChar = nullptr;
BluetoothGattService *bleService = nullptr;
om2jciebuData_t om2jciebuData_ble;
std::string bleMACaddress;
bool is_BleConnected = false;
/**
*connect BLE Device
*
* @param device_address BLE deivce adddress
*
* @return Return success or Failure
*/
bool connectBleDevice(std::string ble_address);
/**
* Start BLE Discovery
*
* @return Return success or Failure
*/
bool startBleDiscovery();
/**
* Stop BLE Discovery
*
* @return Return success or Failure
*/
bool stopBleDiscovery();
/**
* Get sensor data from global struct.
*
* @param attribute_name attribute_name of sensor data
* @param attributeValue Data of attirbute
*/
void getSensorAttribute(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue);
/**
* Verifies the packet header and indicates its valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len);
/**
* Calculate and parse advertise sensor data and store into
* structure
*
* @param data Packet
*
*/
void parseAdvSensorData(uint8_t *data);
/**
* Calculate and parse sensor data and store into
* structure
*
* @param data Packet
*
*/
void parseSensorData(uint8_t *data);
/**
* Write packet over BLE
*
* @param attribute_name attribute_name of sensor
* @param arg_value arg value for write a data over BLE
*
* @return Return success or Failure
*/
bool writePacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, const std::vector<unsigned char> &arg_value);
};
}

16
Omron_2jcie-bu01_ble/upm/src/2jciebu-ble/2jciebu01_ble.i → src/2jciebu01-ble/2jciebu01_ble.i
View File

@ -1,8 +1,8 @@
%include "../common_top.i"
/* BEGIN Common SWIG syntax ------------------------------------------------- */
%{
#include "2jciebu01_ble.hpp"
%}
%include "2jciebu01_ble.hpp"
/* END Common SWIG syntax */
%include "../common_top.i"
/* BEGIN Common SWIG syntax ------------------------------------------------- */
%{
#include "2jciebu01_ble.hpp"
%}
%include "2jciebu01_ble.hpp"
/* END Common SWIG syntax */

58
Omron_2jcie-bu01_ble/upm/src/2jciebu-ble/2jciebu01_ble.json → src/2jciebu01-ble/2jciebu01_ble.json
View File

@ -1,29 +1,29 @@
{
"Library": "2jciebu01_ble",
"Description": "Omron Environment Sensor",
"Sensor Class": {
"OM2JCIEBU_BLE": {
"Name": "API for 2JCIEBU01 Sensor Module using BLE interface",
"Description": "This is the UPM Module for the Omron Environment Sensor Module using BLE interface.",
"Aliases": [""],
"Categories": ["USB"],
"Connections": ["ble"],
"Project Type": ["sensor"],
"Manufacturers": ["Omron"],
"Image": "",
"Examples": {
"C++": ["omron2jciebu01_ble.cxx"]
},
"Platforms": {
"Intel Edison": {
"Notes": ["Might need USB type omron environment sensor"]
}
},
"Urls": {
"Product Pages": ["https://www.components.omron.com/solutions/mems-sensors/environment-sensor"],
"Datasheets": ["https://omronfs.omron.com/en_US/ecb/products/pdf/A279-E1-01.pdf"]
}
}
}
}
{
"Library": "2jciebu01_ble",
"Description": "Omron Environment Sensor",
"Sensor Class": {
"OM2JCIEBU_BLE": {
"Name": "API for 2JCIEBU01 Sensor Module using BLE interface",
"Description": "This is the UPM Module for the Omron Environment Sensor Module using BLE interface.",
"Aliases": [""],
"Categories": ["USB"],
"Connections": ["ble"],
"Project Type": ["sensor"],
"Manufacturers": ["Omron"],
"Image": "",
"Examples": {
"C++": ["omron2jciebu01_ble.cxx"]
},
"Platforms": {
"Intel Edison": {
"Notes": ["Might need USB type omron environment sensor"]
}
},
"Urls": {
"Product Pages": ["https://www.components.omron.com/solutions/mems-sensors/environment-sensor"],
"Datasheets": ["https://omronfs.omron.com/en_US/ecb/products/pdf/A279-E1-01.pdf"]
}
}
}
}

10
Omron_2jcie-bu01_ble/upm/src/2jciebu-ble/CMakeLists.txt → src/2jciebu01-ble/CMakeLists.txt
View File

@ -1,5 +1,5 @@
set (libname "2jciebu01_ble")
set (libdescription "Omron Environment Sensor")
set (module_src ${libname}.cxx "2jciebu01.cxx")
set (module_hpp ${libname}.hpp "2jciebu01.hpp")
upm_module_init(2jciebu01-usb)
set (libname "2jciebu01_ble")
set (libdescription "Omron Environment Sensor")
set (module_src ${libname}.cxx "2jciebu01.cxx")
set (module_hpp ${libname}.hpp "2jciebu01.hpp")
upm_module_init(2jciebu01-usb)

196
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01.cxx → src/2jciebu01-usb/2jciebu01.cxx
View File

@ -1,98 +1,98 @@
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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 <iostream>
#include <string>
#include <stdexcept>
#include "2jciebu01.hpp"
using namespace upm;
using namespace std;
void OM2JCIEBU::getAddress(OM2JCIEBU_ATTRIBUTE_T attribute_name, OM2JCIEBU_INTERFACE_T interface, void *attribute_value)
{
if(attribute_value == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
switch(attribute_name) {
case ALL_PARAM:
case TEMP:
case HUMIDITY:
case AMBIENT_LIGHT:
case PRESSURE:
case NOISE:
case ETVOC:
case ECO2:
case DISCOMFORT_INDEX:
case HEAT_STROKE:
if(interface == USB_TO_UART) //Check for interface
*(uint16_t *)attribute_value = OM2JCIEBU_LIVE_LONG_DATA_READ_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE, strlen(OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE));
break;
case LED_CONFIGURE:
if(interface == USB_TO_UART)
*(uint16_t *)attribute_value = OM2JCIEBU_LED_CONFIGUARTION_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE, strlen(OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE));
break;
case ADV_CONFIGURE:
if(interface == USB_TO_UART)
*(uint16_t *)attribute_value = OM2JCIEBU_ADV_CONFIGUARTION_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE, strlen(OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE));
break;
}
}
void OM2JCIEBU::delay(int second)
{
sleep(second);
}
uint16_t OM2JCIEBU::crc_16(uint8_t *data, int length)
{
/* calculate crc_16 for payload */
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return 0;
}
uint16_t crc = OM2JCIEBU_CRC16, l_outeriterator = 0, l_Inneriterator = 0, carrayFlag = 0;
for(l_outeriterator = 0; l_outeriterator < length; l_outeriterator++) {
crc = crc ^ data[l_outeriterator];
for(l_Inneriterator = 0; l_Inneriterator < 8; l_Inneriterator++) {
carrayFlag = crc & 1;
crc = crc >> 1;
if(carrayFlag == 1) {
crc = crc ^ 0xA001;
}
}
}
return crc;
}
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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 <iostream>
#include <string>
#include <stdexcept>
#include "2jciebu01.hpp"
using namespace upm;
using namespace std;
void OM2JCIEBU::getAddress(OM2JCIEBU_ATTRIBUTE_T attribute_name, OM2JCIEBU_INTERFACE_T interface, void *attribute_value)
{
if(attribute_value == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
switch(attribute_name) {
case ALL_PARAM:
case TEMP:
case HUMIDITY:
case AMBIENT_LIGHT:
case PRESSURE:
case NOISE:
case ETVOC:
case ECO2:
case DISCOMFORT_INDEX:
case HEAT_STROKE:
if(interface == USB_TO_UART) //Check for interface
*(uint16_t *)attribute_value = OM2JCIEBU_LIVE_LONG_DATA_READ_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE, strlen(OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE));
break;
case LED_CONFIGURE:
if(interface == USB_TO_UART)
*(uint16_t *)attribute_value = OM2JCIEBU_LED_CONFIGUARTION_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE, strlen(OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE));
break;
case ADV_CONFIGURE:
if(interface == USB_TO_UART)
*(uint16_t *)attribute_value = OM2JCIEBU_ADV_CONFIGUARTION_ADD_UART;
else
memcpy(attribute_value, OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE, strlen(OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE));
break;
}
}
void OM2JCIEBU::delay(int second)
{
sleep(second);
}
uint16_t OM2JCIEBU::crc_16(uint8_t *data, int length)
{
/* calculate crc_16 for payload */
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return 0;
}
uint16_t crc = OM2JCIEBU_CRC16, l_outeriterator = 0, l_Inneriterator = 0, carrayFlag = 0;
for(l_outeriterator = 0; l_outeriterator < length; l_outeriterator++) {
crc = crc ^ data[l_outeriterator];
for(l_Inneriterator = 0; l_Inneriterator < 8; l_Inneriterator++) {
carrayFlag = crc & 1;
crc = crc >> 1;
if(carrayFlag == 1) {
crc = crc ^ 0xA001;
}
}
}
return crc;
}

480
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01.hpp → src/2jciebu01-usb/2jciebu01.hpp
View File

@ -1,240 +1,240 @@
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include <string>
#include <iostream>
#include <limits>
#include <stdint.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <fcntl.h>
#include <errno.h>
#include <sys/select.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <upm/upm_utilities.h>
/*MACROS and enum */
#define OM2JCIEBU_FLASH_LONG_DATA_READ_ADD_UART 0x500E
#define OM2JCIEBU_LIVE_LONG_DATA_READ_ADD_UART 0x5021
#define OM2JCIEBU_LED_CONFIGUARTION_ADD_UART 0x5111
#define OM2JCIEBU_ADV_CONFIGUARTION_ADD_UART 0x5115
#define OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE "ab705111-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE "ab705115-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE "ab705012-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_CRC_LENGTH 2
#define OM2JCIEBU_CRC16 0xFFFF
#define OM2JCIEBU_INTERVAL_UNIT 0.625
/*=========================================================================*/
namespace upm
{
/**
* @brief omron 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01
* @ingroup Omron USB type
*/
/**
* @library 2jciebu01
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con usb
*
* @brief API for the Omron USB type environment Sensor Module using USB to UART interface
*
* It is connected via a UART at 115200 baud.
*
* @snippet 2jciebu01.cxx Interesting
*/
class OM2JCIEBU
{
public :
typedef enum {
ALL_PARAM,
TEMP,
HUMIDITY,
AMBIENT_LIGHT,
PRESSURE,
NOISE,
ETVOC,
ECO2,
DISCOMFORT_INDEX,
HEAT_STROKE,
LED_CONFIGURE,
ADV_CONFIGURE,
} OM2JCIEBU_ATTRIBUTE_T;
typedef enum {
BLE,
USB_TO_UART
} OM2JCIEBU_INTERFACE_T;
typedef enum {
SENSOR_DATA = 1,
ACCELERATION_DATA,
ACCELERATION_SENSOR_DATA,
ACCELERATION_SENSOR_FLAG,
SERIAL_NUMBER
} OM2JCIEBU_ADV_PARAM_T;
typedef enum {
ERROR_CRC_WRONG = -1,
ERROR_WRONG_COMMAND,
ERROR_WRONG_ADDRESS,
ERROR_WRONG_LENGTH,
ERROR_DATA_RANGE,
ERROR_BUSY,
ERROR_UNKNOWN,
ERROR_CRC_MISMATCH,
FAILURE = 0,
SUCCESS = 1
} OM2JCIEBU_ERROR_T;
typedef enum {
NORMALLY_OFF = 0,
NORMALLY_ON,
TEMP_SACLE,
HUMIDITY_SCALE,
AMBIENT_LIGHT_SCALE,
PRESSURE_SCALE,
NOISE_SCALE,
ETVOC_SCALE,
SI_SCALE,
PGA_SCALE
} OM2JCIEBU_LED_SCALE_T;
typedef struct {
uint8_t sequence_number;
int16_t temperature;
int16_t relative_humidity;
int16_t ambient_light;
int32_t pressure;
int16_t noise;
int16_t eTVOC;
int16_t eCO2;
int16_t discomfort_index;
int16_t heat_stroke;
} __attribute__((packed))om2jciebuData_t;
/**
* OM2JCIEBU destructor
*/
virtual ~OM2JCIEBU() {}
/**
* get address or UUID based on attribute name
*
* @param attribute_name attribute name of sensor
* @param interface Interface name of sensor
* @param attribute_value address value and UUID based on attribute name
*/
void getAddress(OM2JCIEBU_ATTRIBUTE_T attribute_name, OM2JCIEBU_INTERFACE_T interface, void *attribute_value);
/**
* Delay for read sensor data;
*
* @param second second for delay
*/
void delay(int second);
/**
* Calculate crc-16 from the header
* to the end of the payload.
*
* @param data Packet
* @param length length of packet
* @return 16 bit crc of payload
*/
uint16_t crc_16(uint8_t *data, int length);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
virtual void configureSensorLedState(OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue) = 0;
/**
* Set Advertise configuration of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
virtual void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU_ADV_PARAM_T adv_mode) = 0;
/**
* Calculate and parse sensor data and store into
* Sensor data structure
*
* @param data Packet
*
*/
virtual void parseSensorData(uint8_t *data) = 0;
/**
* Get omron sensor live data as per attribute name
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
virtual OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data) = 0;
/**
* Verifies the packet header and indicates it is valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
virtual OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len) = 0;
};
}
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include <string>
#include <iostream>
#include <limits>
#include <stdint.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <fcntl.h>
#include <errno.h>
#include <sys/select.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <upm/upm_utilities.h>
/*MACROS and enum */
#define OM2JCIEBU_FLASH_LONG_DATA_READ_ADD_UART 0x500E
#define OM2JCIEBU_LIVE_LONG_DATA_READ_ADD_UART 0x5021
#define OM2JCIEBU_LED_CONFIGUARTION_ADD_UART 0x5111
#define OM2JCIEBU_ADV_CONFIGUARTION_ADD_UART 0x5115
#define OM2JCIEBU_LED_CONFIGUARTION_UUID_BLE "ab705111-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_ADV_CONFIGUARTION_UUID_BLE "ab705115-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_LIVE_LONG_DATA_READ_UUID_BLE "ab705012-0a3a-11e8-ba89-0ed5f89f718b"
#define OM2JCIEBU_CRC_LENGTH 2
#define OM2JCIEBU_CRC16 0xFFFF
#define OM2JCIEBU_INTERVAL_UNIT 0.625
/*=========================================================================*/
namespace upm
{
/**
* @brief omron 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01
* @ingroup Omron USB type
*/
/**
* @library 2jciebu01
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con usb
*
* @brief API for the Omron USB type environment Sensor Module using USB to UART interface
*
* It is connected via a UART at 115200 baud.
*
* @snippet 2jciebu01.cxx Interesting
*/
class OM2JCIEBU
{
public :
typedef enum {
ALL_PARAM,
TEMP,
HUMIDITY,
AMBIENT_LIGHT,
PRESSURE,
NOISE,
ETVOC,
ECO2,
DISCOMFORT_INDEX,
HEAT_STROKE,
LED_CONFIGURE,
ADV_CONFIGURE,
} OM2JCIEBU_ATTRIBUTE_T;
typedef enum {
BLE,
USB_TO_UART
} OM2JCIEBU_INTERFACE_T;
typedef enum {
SENSOR_DATA = 1,
ACCELERATION_DATA,
ACCELERATION_SENSOR_DATA,
ACCELERATION_SENSOR_FLAG,
SERIAL_NUMBER
} OM2JCIEBU_ADV_PARAM_T;
typedef enum {
ERROR_CRC_WRONG = -1,
ERROR_WRONG_COMMAND,
ERROR_WRONG_ADDRESS,
ERROR_WRONG_LENGTH,
ERROR_DATA_RANGE,
ERROR_BUSY,
ERROR_UNKNOWN,
ERROR_CRC_MISMATCH,
FAILURE = 0,
SUCCESS = 1
} OM2JCIEBU_ERROR_T;
typedef enum {
NORMALLY_OFF = 0,
NORMALLY_ON,
TEMP_SACLE,
HUMIDITY_SCALE,
AMBIENT_LIGHT_SCALE,
PRESSURE_SCALE,
NOISE_SCALE,
ETVOC_SCALE,
SI_SCALE,
PGA_SCALE
} OM2JCIEBU_LED_SCALE_T;
typedef struct {
uint8_t sequence_number;
int16_t temperature;
int16_t relative_humidity;
int16_t ambient_light;
int32_t pressure;
int16_t noise;
int16_t eTVOC;
int16_t eCO2;
int16_t discomfort_index;
int16_t heat_stroke;
} __attribute__((packed))om2jciebuData_t;
/**
* OM2JCIEBU destructor
*/
virtual ~OM2JCIEBU() {}
/**
* get address or UUID based on attribute name
*
* @param attribute_name attribute name of sensor
* @param interface Interface name of sensor
* @param attribute_value address value and UUID based on attribute name
*/
void getAddress(OM2JCIEBU_ATTRIBUTE_T attribute_name, OM2JCIEBU_INTERFACE_T interface, void *attribute_value);
/**
* Delay for read sensor data;
*
* @param second second for delay
*/
void delay(int second);
/**
* Calculate crc-16 from the header
* to the end of the payload.
*
* @param data Packet
* @param length length of packet
* @return 16 bit crc of payload
*/
uint16_t crc_16(uint8_t *data, int length);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
virtual void configureSensorLedState(OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue) = 0;
/**
* Set Advertise configuration of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
virtual void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU_ADV_PARAM_T adv_mode) = 0;
/**
* Calculate and parse sensor data and store into
* Sensor data structure
*
* @param data Packet
*
*/
virtual void parseSensorData(uint8_t *data) = 0;
/**
* Get omron sensor live data as per attribute name
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
virtual OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data) = 0;
/**
* Verifies the packet header and indicates it is valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
virtual OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len) = 0;
};
}

702
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01_usb.cxx → src/2jciebu01-usb/2jciebu01_usb.cxx
View File

@ -1,351 +1,351 @@
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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 <iostream>
#include <string>
#include <stdexcept>
#include "2jciebu01_usb.hpp"
using namespace upm;
using namespace std;
static const int defaultDelay = 1000; // max wait time for read
OM2JCIEBU_UART::OM2JCIEBU_UART(std::string uart_raw, int baud) : m_uart(uart_raw)
{
if(!setupTty(baud))
throw std::runtime_error(std::string(__FUNCTION__) +
": failed to set baud rate to " + std::to_string(baud));
}
bool OM2JCIEBU_UART::setupTty(uint32_t baud)
{
return m_uart.setBaudRate(baud) == mraa::SUCCESS;
}
uint8_t OM2JCIEBU_UART::setMode(int bytesize, mraa::UartParity parity, int stopbits)
{
return m_uart.setMode(bytesize, parity, stopbits);
}
uint8_t OM2JCIEBU_UART::setFlowControl(bool xonxoff, bool rtscts)
{
return m_uart.setFlowcontrol(xonxoff, rtscts);
}
int OM2JCIEBU_UART::readData(char *buffer, int len)
{
if(buffer == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
if(!m_uart.dataAvailable(defaultDelay)) //time out for read UART data
return 0;
int rv = m_uart.read(buffer, len);
//check for UART read fail
if(rv < 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::read() failed: " + string(strerror(errno)));
return rv;
}
int OM2JCIEBU_UART::writeData(char *buffer, int len)
{
if(buffer == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
int rv = m_uart.write(buffer, len);
//check for UART write fail
if(rv < 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::write() failed: " +
string(strerror(errno)));
//check for UART write fail
if(rv == 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::write() failed, no bytes written");
return rv;
}
int OM2JCIEBU_UART::readCmdPacket(OM2JCIEBU_UART::OM2JCIEBU_ATTRIBUTE_T attribute_name)
{
/* Create a payload as per OMRON uart frame format*/
uint8_t omPkt[OM2JCIEBU_UART_MAX_PKT_LEN] = {0};
uint16_t pktLength = 0, crc = 0, pktIndex = 0, address = 0;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_START;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_END;
pktLength = OM2JCIEBU_CRC_LENGTH + OM2JCIEBU_UART_ADDRESS_LENGTH + OM2JCIEBU_UART_COMMAND_LENGHT;
omPkt[pktIndex++] = pktLength & 0x00FF;
omPkt[pktIndex++] = pktLength >> 8;
omPkt[pktIndex++] = UART_CMD_READ;
getAddress(attribute_name, USB_TO_UART, &address);
omPkt[pktIndex++] = address & 0x00FF;
omPkt[pktIndex++] = address >> 8;
crc = crc_16(omPkt, pktIndex);
omPkt[pktIndex++] = crc & 0x00FF;
omPkt[pktIndex++] = crc >> 8;
return (writeData((char *)omPkt, pktIndex));
}
void OM2JCIEBU_UART::configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode)
{
uint8_t adv_config[3] = {0};
uint16_t interval;
interval = milliseconds / OM2JCIEBU_INTERVAL_UNIT; /*calculate interval which is given by user using interval unit */
adv_config[0] = interval & 0x00FF;
adv_config[1] = interval >> 8;
adv_config[2] = adv_mode;
writeCmdPacket(ADV_CONFIGURE, adv_config, sizeof(adv_config));
}
void OM2JCIEBU_UART::configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue)
{
uint8_t led_config[5] = {0};
led_config[0] = state;
led_config[1] = 0x00;
led_config[2] = red;
led_config[3] = green;
led_config[4] = blue;
writeCmdPacket(LED_CONFIGURE, led_config, sizeof(led_config));
}
int OM2JCIEBU_UART::writeCmdPacket(OM2JCIEBU_UART::OM2JCIEBU_ATTRIBUTE_T attribute_name, uint8_t *data, uint16_t length)
{
/* Create a frame formate for write a data on UART as per common frame formate*/
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
uint8_t omPkt[OM2JCIEBU_UART_MAX_PKT_LEN] = {0};
uint16_t pktLength = 0, crc = 0, pktIndex = 0, l_iterator = 0, address = 0;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_START;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_END;
pktLength = OM2JCIEBU_CRC_LENGTH + OM2JCIEBU_UART_ADDRESS_LENGTH + OM2JCIEBU_UART_COMMAND_LENGHT + length;
omPkt[pktIndex++] = pktLength & 0x00FF;
omPkt[pktIndex++] = pktLength >> 8;
omPkt[pktIndex++] = UART_CMD_WRITE;
getAddress(attribute_name, USB_TO_UART, &address);
omPkt[pktIndex++] = address & 0x00FF;
omPkt[pktIndex++] = address >> 8;
for(l_iterator = 0; l_iterator < length; l_iterator++) {
omPkt[pktIndex++] = data[l_iterator];
}
crc = crc_16(omPkt, pktIndex);
omPkt[pktIndex++] = crc & 0x00FF;
omPkt[pktIndex++] = crc >> 8;
return (writeData((char *)omPkt, pktIndex));
}
void OM2JCIEBU_UART::getSensorAttribute(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue)
{
/* Assign sensor value attributes to void pointer*/
if(attributeValue == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
switch(attribute_name) {
case ALL_PARAM:
memcpy(attributeValue, &om2jciebuData_uart, sizeof(om2jciebuData_uart));
break;
case TEMP:
*(int16_t *) attributeValue = om2jciebuData_uart.temperature;
break;
case HUMIDITY:
*(int16_t *) attributeValue = om2jciebuData_uart.relative_humidity;
break;
case AMBIENT_LIGHT:
*(int16_t *) attributeValue = om2jciebuData_uart.ambient_light;
break;
case PRESSURE:
*(int32_t *) attributeValue = om2jciebuData_uart.pressure;
break;
case NOISE:
*(int16_t *) attributeValue = om2jciebuData_uart.noise;
break;
case ETVOC:
*(int16_t *) attributeValue = om2jciebuData_uart.eTVOC;
break;
case ECO2:
*(int16_t *) attributeValue = om2jciebuData_uart.eCO2;
break;
case DISCOMFORT_INDEX:
*(int16_t *) attributeValue = om2jciebuData_uart.discomfort_index;
break;
case HEAT_STROKE:
*(int16_t *) attributeValue = om2jciebuData_uart.heat_stroke;
break;
case LED_CONFIGURE:
break;
case ADV_CONFIGURE:
break;
}
}
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T OM2JCIEBU_UART::getSensorData(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data)
{
if(attribute_data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
//create a payload frame for read sensor data
readCmdPacket(attribute_name);
char buf[OM2JCIEBU_UART_MAX_READ_PKT_LEN];
uint8_t pkt[OM2JCIEBU_UART_MAX_PKT_LEN];
int rv;
int8_t pkt_index = 0, idx = 0;
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T verifyResult = FAILURE;
//read from UART
while(true) {
rv = readData(buf, OM2JCIEBU_UART_MAX_READ_PKT_LEN);
if(rv > 0) {
for(idx = 0; idx < rv; idx++)
pkt[pkt_index++] = buf[idx];
} else {
verifyResult = verifyPacket(pkt, pkt_index);
if(verifyResult == SUCCESS) {
break;
} else {
return verifyResult;
}
}
}
//calculate a data and store in struct
parseSensorData(pkt);
//copy data to user provided pointer
getSensorAttribute(attribute_name, attribute_data);
return verifyResult;
}
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T OM2JCIEBU_UART::verifyPacket(uint8_t *pkt, int len)
{
if(pkt == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
uint16_t crc = 0;
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T verifyResult = FAILURE;
//Verify a data which is read from UART buffer
if((pkt[OM2JCIEBU_UART_COMMAND_INDEX] & 0xF0) == 0x80) { //Check for error in payload
if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_CRC_WRONG) {
std::cout << "Error CRC wrong" << std::endl;
verifyResult = ERROR_CRC_WRONG;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_COMMAND) {
std::cout << "Error Invalid Command" << std::endl;
verifyResult = ERROR_WRONG_COMMAND;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_ADDRESS) {
std::cout << "Error Invalid Address" << std::endl;
verifyResult = ERROR_WRONG_ADDRESS;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_LENGTH) {
std::cout << "Error Invalid Length" << std::endl;
verifyResult = ERROR_WRONG_LENGTH;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_DATA_RANGE) {
std::cout << "Error Invalid Data Range" << std::endl;
verifyResult = ERROR_DATA_RANGE;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_BUSY) {
std::cout << "Uart is BUSY" << std::endl;
verifyResult = ERROR_BUSY;
}
} else if((pkt[OM2JCIEBU_UART_COMMAND_INDEX] & 0xFF) == 0xFF) { //Check for unknow error in UART frame
std::cout << "Invalid reponse" << std::endl;
verifyResult = ERROR_UNKNOWN;
} else {
crc = crc_16(pkt, (len - OM2JCIEBU_CRC_LENGTH)); //Check for CRC which is read from UART frame
if(pkt[len - OM2JCIEBU_CRC_LENGTH] == (crc & 0x00FF) && pkt[len - 1] == crc >> 8) {
verifyResult = SUCCESS;
} else {
std::cout << "Does not match CRC" << std::endl;
verifyResult = ERROR_CRC_MISMATCH;
}
}
return verifyResult;
}
void OM2JCIEBU_UART::parseSensorData(uint8_t *data)
{
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
//Parse data after payload verfication
om2jciebuData_uart.sequence_number = data[7];
om2jciebuData_uart.temperature = data[8] | data[9] << 8;
om2jciebuData_uart.temperature = om2jciebuData_uart.temperature / 100;
om2jciebuData_uart.relative_humidity = data[10] | data[11] << 8;
om2jciebuData_uart.relative_humidity = om2jciebuData_uart.relative_humidity / 100;
om2jciebuData_uart.ambient_light = data[12] | data[13] << 8;
om2jciebuData_uart.pressure = data[14] | data[15] << 8 | data[16] << 16 | data[17] << 24;
om2jciebuData_uart.pressure = om2jciebuData_uart.pressure / 1000;
om2jciebuData_uart.noise = data[18] | data[19] << 8;
om2jciebuData_uart.noise = om2jciebuData_uart.noise / 100;
om2jciebuData_uart.eTVOC = data[20] | data[21] << 8;
om2jciebuData_uart.eCO2 = data[22] | data[23] << 8;
om2jciebuData_uart.discomfort_index = data[24] | data[25] << 8;
om2jciebuData_uart.discomfort_index = om2jciebuData_uart.discomfort_index / 100;
om2jciebuData_uart.heat_stroke = data[26] | data[27] << 8;
om2jciebuData_uart.heat_stroke = om2jciebuData_uart.heat_stroke / 100;
}
/*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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 <iostream>
#include <string>
#include <stdexcept>
#include "2jciebu01_usb.hpp"
using namespace upm;
using namespace std;
static const int defaultDelay = 1000; // max wait time for read
OM2JCIEBU_UART::OM2JCIEBU_UART(std::string uart_raw, int baud) : m_uart(uart_raw)
{
if(!setupTty(baud))
throw std::runtime_error(std::string(__FUNCTION__) +
": failed to set baud rate to " + std::to_string(baud));
}
bool OM2JCIEBU_UART::setupTty(uint32_t baud)
{
return m_uart.setBaudRate(baud) == mraa::SUCCESS;
}
uint8_t OM2JCIEBU_UART::setMode(int bytesize, mraa::UartParity parity, int stopbits)
{
return m_uart.setMode(bytesize, parity, stopbits);
}
uint8_t OM2JCIEBU_UART::setFlowControl(bool xonxoff, bool rtscts)
{
return m_uart.setFlowcontrol(xonxoff, rtscts);
}
int OM2JCIEBU_UART::readData(char *buffer, int len)
{
if(buffer == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
if(!m_uart.dataAvailable(defaultDelay)) //time out for read UART data
return 0;
int rv = m_uart.read(buffer, len);
//check for UART read fail
if(rv < 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::read() failed: " + string(strerror(errno)));
return rv;
}
int OM2JCIEBU_UART::writeData(char *buffer, int len)
{
if(buffer == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
int rv = m_uart.write(buffer, len);
//check for UART write fail
if(rv < 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::write() failed: " +
string(strerror(errno)));
//check for UART write fail
if(rv == 0)
throw std::runtime_error(std::string(__FUNCTION__) +
": Uart::write() failed, no bytes written");
return rv;
}
int OM2JCIEBU_UART::readCmdPacket(OM2JCIEBU_UART::OM2JCIEBU_ATTRIBUTE_T attribute_name)
{
/* Create a payload as per OMRON uart frame format*/
uint8_t omPkt[OM2JCIEBU_UART_MAX_PKT_LEN] = {0};
uint16_t pktLength = 0, crc = 0, pktIndex = 0, address = 0;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_START;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_END;
pktLength = OM2JCIEBU_CRC_LENGTH + OM2JCIEBU_UART_ADDRESS_LENGTH + OM2JCIEBU_UART_COMMAND_LENGHT;
omPkt[pktIndex++] = pktLength & 0x00FF;
omPkt[pktIndex++] = pktLength >> 8;
omPkt[pktIndex++] = UART_CMD_READ;
getAddress(attribute_name, USB_TO_UART, &address);
omPkt[pktIndex++] = address & 0x00FF;
omPkt[pktIndex++] = address >> 8;
crc = crc_16(omPkt, pktIndex);
omPkt[pktIndex++] = crc & 0x00FF;
omPkt[pktIndex++] = crc >> 8;
return (writeData((char *)omPkt, pktIndex));
}
void OM2JCIEBU_UART::configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode)
{
uint8_t adv_config[3] = {0};
uint16_t interval;
interval = milliseconds / OM2JCIEBU_INTERVAL_UNIT; /*calculate interval which is given by user using interval unit */
adv_config[0] = interval & 0x00FF;
adv_config[1] = interval >> 8;
adv_config[2] = adv_mode;
writeCmdPacket(ADV_CONFIGURE, adv_config, sizeof(adv_config));
}
void OM2JCIEBU_UART::configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue)
{
uint8_t led_config[5] = {0};
led_config[0] = state;
led_config[1] = 0x00;
led_config[2] = red;
led_config[3] = green;
led_config[4] = blue;
writeCmdPacket(LED_CONFIGURE, led_config, sizeof(led_config));
}
int OM2JCIEBU_UART::writeCmdPacket(OM2JCIEBU_UART::OM2JCIEBU_ATTRIBUTE_T attribute_name, uint8_t *data, uint16_t length)
{
/* Create a frame formate for write a data on UART as per common frame formate*/
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
uint8_t omPkt[OM2JCIEBU_UART_MAX_PKT_LEN] = {0};
uint16_t pktLength = 0, crc = 0, pktIndex = 0, l_iterator = 0, address = 0;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_START;
omPkt[pktIndex++] = OM2JCIEBU_UART_HEADER_END;
pktLength = OM2JCIEBU_CRC_LENGTH + OM2JCIEBU_UART_ADDRESS_LENGTH + OM2JCIEBU_UART_COMMAND_LENGHT + length;
omPkt[pktIndex++] = pktLength & 0x00FF;
omPkt[pktIndex++] = pktLength >> 8;
omPkt[pktIndex++] = UART_CMD_WRITE;
getAddress(attribute_name, USB_TO_UART, &address);
omPkt[pktIndex++] = address & 0x00FF;
omPkt[pktIndex++] = address >> 8;
for(l_iterator = 0; l_iterator < length; l_iterator++) {
omPkt[pktIndex++] = data[l_iterator];
}
crc = crc_16(omPkt, pktIndex);
omPkt[pktIndex++] = crc & 0x00FF;
omPkt[pktIndex++] = crc >> 8;
return (writeData((char *)omPkt, pktIndex));
}
void OM2JCIEBU_UART::getSensorAttribute(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue)
{
/* Assign sensor value attributes to void pointer*/
if(attributeValue == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
switch(attribute_name) {
case ALL_PARAM:
memcpy(attributeValue, &om2jciebuData_uart, sizeof(om2jciebuData_uart));
break;
case TEMP:
*(int16_t *) attributeValue = om2jciebuData_uart.temperature;
break;
case HUMIDITY:
*(int16_t *) attributeValue = om2jciebuData_uart.relative_humidity;
break;
case AMBIENT_LIGHT:
*(int16_t *) attributeValue = om2jciebuData_uart.ambient_light;
break;
case PRESSURE:
*(int32_t *) attributeValue = om2jciebuData_uart.pressure;
break;
case NOISE:
*(int16_t *) attributeValue = om2jciebuData_uart.noise;
break;
case ETVOC:
*(int16_t *) attributeValue = om2jciebuData_uart.eTVOC;
break;
case ECO2:
*(int16_t *) attributeValue = om2jciebuData_uart.eCO2;
break;
case DISCOMFORT_INDEX:
*(int16_t *) attributeValue = om2jciebuData_uart.discomfort_index;
break;
case HEAT_STROKE:
*(int16_t *) attributeValue = om2jciebuData_uart.heat_stroke;
break;
case LED_CONFIGURE:
break;
case ADV_CONFIGURE:
break;
}
}
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T OM2JCIEBU_UART::getSensorData(OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data)
{
if(attribute_data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
//create a payload frame for read sensor data
readCmdPacket(attribute_name);
char buf[OM2JCIEBU_UART_MAX_READ_PKT_LEN];
uint8_t pkt[OM2JCIEBU_UART_MAX_PKT_LEN];
int rv;
int8_t pkt_index = 0, idx = 0;
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T verifyResult = FAILURE;
//read from UART
while(true) {
rv = readData(buf, OM2JCIEBU_UART_MAX_READ_PKT_LEN);
if(rv > 0) {
for(idx = 0; idx < rv; idx++)
pkt[pkt_index++] = buf[idx];
} else {
verifyResult = verifyPacket(pkt, pkt_index);
if(verifyResult == SUCCESS) {
break;
} else {
return verifyResult;
}
}
}
//calculate a data and store in struct
parseSensorData(pkt);
//copy data to user provided pointer
getSensorAttribute(attribute_name, attribute_data);
return verifyResult;
}
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T OM2JCIEBU_UART::verifyPacket(uint8_t *pkt, int len)
{
if(pkt == NULL) {
std::cout << "Null pointer received..." << std::endl;
return FAILURE;
}
uint16_t crc = 0;
OM2JCIEBU_UART::OM2JCIEBU_ERROR_T verifyResult = FAILURE;
//Verify a data which is read from UART buffer
if((pkt[OM2JCIEBU_UART_COMMAND_INDEX] & 0xF0) == 0x80) { //Check for error in payload
if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_CRC_WRONG) {
std::cout << "Error CRC wrong" << std::endl;
verifyResult = ERROR_CRC_WRONG;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_COMMAND) {
std::cout << "Error Invalid Command" << std::endl;
verifyResult = ERROR_WRONG_COMMAND;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_ADDRESS) {
std::cout << "Error Invalid Address" << std::endl;
verifyResult = ERROR_WRONG_ADDRESS;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_WRONG_LENGTH) {
std::cout << "Error Invalid Length" << std::endl;
verifyResult = ERROR_WRONG_LENGTH;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_DATA_RANGE) {
std::cout << "Error Invalid Data Range" << std::endl;
verifyResult = ERROR_DATA_RANGE;
} else if(pkt[OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX] == ERROR_UART_BUSY) {
std::cout << "Uart is BUSY" << std::endl;
verifyResult = ERROR_BUSY;
}
} else if((pkt[OM2JCIEBU_UART_COMMAND_INDEX] & 0xFF) == 0xFF) { //Check for unknow error in UART frame
std::cout << "Invalid reponse" << std::endl;
verifyResult = ERROR_UNKNOWN;
} else {
crc = crc_16(pkt, (len - OM2JCIEBU_CRC_LENGTH)); //Check for CRC which is read from UART frame
if(pkt[len - OM2JCIEBU_CRC_LENGTH] == (crc & 0x00FF) && pkt[len - 1] == crc >> 8) {
verifyResult = SUCCESS;
} else {
std::cout << "Does not match CRC" << std::endl;
verifyResult = ERROR_CRC_MISMATCH;
}
}
return verifyResult;
}
void OM2JCIEBU_UART::parseSensorData(uint8_t *data)
{
if(data == NULL) {
std::cout << "Null pointer received..." << std::endl;
return;
}
//Parse data after payload verfication
om2jciebuData_uart.sequence_number = data[7];
om2jciebuData_uart.temperature = data[8] | data[9] << 8;
om2jciebuData_uart.temperature = om2jciebuData_uart.temperature / 100;
om2jciebuData_uart.relative_humidity = data[10] | data[11] << 8;
om2jciebuData_uart.relative_humidity = om2jciebuData_uart.relative_humidity / 100;
om2jciebuData_uart.ambient_light = data[12] | data[13] << 8;
om2jciebuData_uart.pressure = data[14] | data[15] << 8 | data[16] << 16 | data[17] << 24;
om2jciebuData_uart.pressure = om2jciebuData_uart.pressure / 1000;
om2jciebuData_uart.noise = data[18] | data[19] << 8;
om2jciebuData_uart.noise = om2jciebuData_uart.noise / 100;
om2jciebuData_uart.eTVOC = data[20] | data[21] << 8;
om2jciebuData_uart.eCO2 = data[22] | data[23] << 8;
om2jciebuData_uart.discomfort_index = data[24] | data[25] << 8;
om2jciebuData_uart.discomfort_index = om2jciebuData_uart.discomfort_index / 100;
om2jciebuData_uart.heat_stroke = data[26] | data[27] << 8;
om2jciebuData_uart.heat_stroke = om2jciebuData_uart.heat_stroke / 100;
}

494
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01_usb.hpp → src/2jciebu01-usb/2jciebu01_usb.hpp
View File

@ -1,247 +1,247 @@
/*
*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include "mraa.hpp"
#include "2jciebu01.hpp"
/*MACROS and enum */
// protocol start codes
#define OM2JCIEBU_UART_HEADER_START 0x52
#define OM2JCIEBU_UART_HEADER_END 0x42
#define OM2JCIEBU_UART_MAX_PKT_LEN 256
#define OM2JCIEBU_UART_MAX_READ_PKT_LEN 10
#define OM2JCIEBU_UART_COMMAND_LENGHT 1
#define OM2JCIEBU_UART_ADDRESS_LENGTH 2
#define OM2JCIEBU_UART_HEADER_LENGTH 2
#define OM2JCIEBU_UART_COMMAND_INDEX 0x04
#define OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX 0x07
/*=========================================================================*/
namespace upm
{
/**
* @brief 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01_usb
* @ingroup Omron USB type
*/
/**
* @library libupm-2jciebu01_usb
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con usb
*
* @brief API for the Omron USB type environment Sensor Module using USB to UART interface
*
* It is connected via a UART at 115200 baud.
*
* @snippet 2jciebu01_usb.cxx Interesting
*/
class OM2JCIEBU_UART : public OM2JCIEBU
{
public :
typedef enum {
UART_CMD_READ = 0x01,
UART_CMD_WRITE = 0x02
} OM2JCIEBU_UART_COMMAND_T;
typedef enum {
ERROR_UART_CRC_WRONG = 0x01,
ERROR_UART_WRONG_COMMAND = 0x02,
ERROR_UART_WRONG_ADDRESS = 0x03,
ERROR_UART_WRONG_LENGTH = 0x04,
ERROR_UART_DATA_RANGE = 0x05,
ERROR_UART_BUSY = 0x06,
ERROR_UART_UNKNOWN = 0XFF
} OM2JCIEBU_UART_ERROR_T;
typedef enum {
PARITY_UART_NONE = 0,
PARITY_UART_EVEN = 1,
PARITY_UART_ODD = 2,
PARITY_UART_MARK = 3,
PARITY_UART_SPACE = 4
} OM2JCIEBU_UART_PARITY_T;
/**
* OM2JCIEBU_UART Constructor, takes a string to the path of the serial
* interface that is needed.
*
* @param uart File path (/dev/ttyXXX to uart
* @param baud Desired baud rate
*/
OM2JCIEBU_UART(std::string path, int baud = 115200);
/**
* Sets up proper tty I/O modes and the baud rate. For this device,
* the default baud rate is 115200.
*
* @param baud Desired baud rate.
* @return True if successful
*/
bool setupTty(uint32_t baud = 115200);
/**
* Set the transfer mode
* For example setting the mode to 8N1 would be
* "dev.setMode(8,PARITY_NONE , 1)"
*
* @param bytesize data bits
* @param parity Parity bit setting
* @param stopbits stop bits
*
* @return Return success or Failure
*/
uint8_t setMode(int bytesize, mraa::UartParity parity, int stopbits);
/**
* Set the flowcontrol
*
* @param xonxoff XON/XOFF Software flow control.
* @param rtscts RTS/CTS out of band hardware flow control
* @return Return success or Failure
*/
uint8_t setFlowControl(bool xonxoff, bool rtscts);
/**
* Get omron sensor live data as per request
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
void configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue);
/**
* Set Advertise interval setting of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode);
private:
mraa::Uart m_uart;
om2jciebuData_t om2jciebuData_uart;
/**
* Composes write command packet and Writes the data
* in the buffer to the device
*
* @param attribute_name Attribute name of sensor
* @param data data for write on particular address
* @param length length of data
* @return Number of bytes written
*/
int writeCmdPacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, uint8_t *data, uint16_t length);
/**
* Composes read command packet and Writes the data
* in the buffer to the device
*
* @param attribute_name Attribute name of sensor
* @return Number of bytes written
*/
int readCmdPacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name);
/**
* Get sensor data from global struct.
*
* @param attributeValue Data of attirbute
*
*/
void getSensorAttribute(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue);
/**
* Writes the data in the buffer to the device
*
* @param buffer Buffer to hold the data read
* @param len Length of the buffer
* @return Number of bytes written
*/
int writeData(char *buffer, int len);
/**
* Reads any available data in a user-supplied buffer. Note: the
* call blocks until data is available to be read. Use
* dataAvailable() to determine whether there is data available
* beforehand, to avoid blocking.
*
* @param buffer Buffer to hold the data read
* @param len Length of the buffer
* @return Number of bytes read
*/
int readData(char *buffer, int len);
/**
* Verifies the packet header and indicates it is valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len);
/**
* Calculate and parse sensor data and store into
* Sensor data structure
*
* @param data Packet
*
*/
void parseSensorData(uint8_t *data);
};
}
/*
*
* Author: Hiroyuki Mino <omronsupportupm@omron.com>
* Copyright (c) 2019 Omron Electronic Components - Americas
*
* 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.
*/
/*=========================================================================*/
#pragma once
#include "mraa.hpp"
#include "2jciebu01.hpp"
/*MACROS and enum */
// protocol start codes
#define OM2JCIEBU_UART_HEADER_START 0x52
#define OM2JCIEBU_UART_HEADER_END 0x42
#define OM2JCIEBU_UART_MAX_PKT_LEN 256
#define OM2JCIEBU_UART_MAX_READ_PKT_LEN 10
#define OM2JCIEBU_UART_COMMAND_LENGHT 1
#define OM2JCIEBU_UART_ADDRESS_LENGTH 2
#define OM2JCIEBU_UART_HEADER_LENGTH 2
#define OM2JCIEBU_UART_COMMAND_INDEX 0x04
#define OM2JCIEBU_UART_COMMAND_ERROR_CODE_INDEX 0x07
/*=========================================================================*/
namespace upm
{
/**
* @brief 2JCIEBU01 Environment sensor
* @defgroup 2jciebu01 libupm-2jciebu01_usb
* @ingroup Omron USB type
*/
/**
* @library libupm-2jciebu01_usb
* @sensor 2jciebu01
* @comname Environment Sensor Module
* @altname Omron Environment sensor USB type
* @type USB
* @man Omron
* @web https://www.components.omron.com/solutions/mems-sensors/environment-sensor
* @con usb
*
* @brief API for the Omron USB type environment Sensor Module using USB to UART interface
*
* It is connected via a UART at 115200 baud.
*
* @snippet 2jciebu01_usb.cxx Interesting
*/
class OM2JCIEBU_UART : public OM2JCIEBU
{
public :
typedef enum {
UART_CMD_READ = 0x01,
UART_CMD_WRITE = 0x02
} OM2JCIEBU_UART_COMMAND_T;
typedef enum {
ERROR_UART_CRC_WRONG = 0x01,
ERROR_UART_WRONG_COMMAND = 0x02,
ERROR_UART_WRONG_ADDRESS = 0x03,
ERROR_UART_WRONG_LENGTH = 0x04,
ERROR_UART_DATA_RANGE = 0x05,
ERROR_UART_BUSY = 0x06,
ERROR_UART_UNKNOWN = 0XFF
} OM2JCIEBU_UART_ERROR_T;
typedef enum {
PARITY_UART_NONE = 0,
PARITY_UART_EVEN = 1,
PARITY_UART_ODD = 2,
PARITY_UART_MARK = 3,
PARITY_UART_SPACE = 4
} OM2JCIEBU_UART_PARITY_T;
/**
* OM2JCIEBU_UART Constructor, takes a string to the path of the serial
* interface that is needed.
*
* @param uart File path (/dev/ttyXXX to uart
* @param baud Desired baud rate
*/
OM2JCIEBU_UART(std::string path, int baud = 115200);
/**
* Sets up proper tty I/O modes and the baud rate. For this device,
* the default baud rate is 115200.
*
* @param baud Desired baud rate.
* @return True if successful
*/
bool setupTty(uint32_t baud = 115200);
/**
* Set the transfer mode
* For example setting the mode to 8N1 would be
* "dev.setMode(8,PARITY_NONE , 1)"
*
* @param bytesize data bits
* @param parity Parity bit setting
* @param stopbits stop bits
*
* @return Return success or Failure
*/
uint8_t setMode(int bytesize, mraa::UartParity parity, int stopbits);
/**
* Set the flowcontrol
*
* @param xonxoff XON/XOFF Software flow control.
* @param rtscts RTS/CTS out of band hardware flow control
* @return Return success or Failure
*/
uint8_t setFlowControl(bool xonxoff, bool rtscts);
/**
* Get omron sensor live data as per request
*
* @param attribute_name Name of attribute
* @param attribute_data Data of attirbute
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T getSensorData(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attribute_data);
/**
* Set LED configartion of sensor
*
* @param state state for led configuartion
* @param red value of red
* @param green value of green
* @param blue value of blue
*/
void configureSensorLedState(OM2JCIEBU::OM2JCIEBU_LED_SCALE_T state, uint8_t red, uint8_t green, uint8_t blue);
/**
* Set Advertise interval setting of sensor
*
* @param miliseconds interval for Advertise data
* @param adv_mode Advertise mode
*/
void configureSensorAdvSetting(uint16_t milliseconds, OM2JCIEBU::OM2JCIEBU_ADV_PARAM_T adv_mode);
private:
mraa::Uart m_uart;
om2jciebuData_t om2jciebuData_uart;
/**
* Composes write command packet and Writes the data
* in the buffer to the device
*
* @param attribute_name Attribute name of sensor
* @param data data for write on particular address
* @param length length of data
* @return Number of bytes written
*/
int writeCmdPacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, uint8_t *data, uint16_t length);
/**
* Composes read command packet and Writes the data
* in the buffer to the device
*
* @param attribute_name Attribute name of sensor
* @return Number of bytes written
*/
int readCmdPacket(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name);
/**
* Get sensor data from global struct.
*
* @param attributeValue Data of attirbute
*
*/
void getSensorAttribute(OM2JCIEBU::OM2JCIEBU_ATTRIBUTE_T attribute_name, void *attributeValue);
/**
* Writes the data in the buffer to the device
*
* @param buffer Buffer to hold the data read
* @param len Length of the buffer
* @return Number of bytes written
*/
int writeData(char *buffer, int len);
/**
* Reads any available data in a user-supplied buffer. Note: the
* call blocks until data is available to be read. Use
* dataAvailable() to determine whether there is data available
* beforehand, to avoid blocking.
*
* @param buffer Buffer to hold the data read
* @param len Length of the buffer
* @return Number of bytes read
*/
int readData(char *buffer, int len);
/**
* Verifies the packet header and indicates it is valid or not
*
* @param pkt Packet to check
* @param len length of packet
* @return One of the OM2JCIEBU_ERROR_T values
*/
OM2JCIEBU_ERROR_T verifyPacket(uint8_t *pkt, int len);
/**
* Calculate and parse sensor data and store into
* Sensor data structure
*
* @param data Packet
*
*/
void parseSensorData(uint8_t *data);
};
}

16
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01_usb.i → src/2jciebu01-usb/2jciebu01_usb.i
View File

@ -1,8 +1,8 @@
%include "../common_top.i"
/* BEGIN Common SWIG syntax ------------------------------------------------- */
%{
#include "2jciebu01_usb.hpp"
%}
%include "2jciebu01_usb.hpp"
/* END Common SWIG syntax */
%include "../common_top.i"
/* BEGIN Common SWIG syntax ------------------------------------------------- */
%{
#include "2jciebu01_usb.hpp"
%}
%include "2jciebu01_usb.hpp"
/* END Common SWIG syntax */

70
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/2jciebu01_usb.json → src/2jciebu01-usb/2jciebu01_usb.json
View File

@ -1,35 +1,35 @@
{
"Library": "2jciebu01_usb",
"Description": "Omron USB type enviroment sensor",
"Sensor Class": {
"OM2JCIEBU_UART": {
"Name": "API for 2JCIEBU01 Sensor Module using USB to UART interface",
"Description": "This is the UPM Module for the Omron Enviroment Sensor Module using USB to UART interface.",
"Aliases": [""],
"Categories": ["USB"],
"Connections": ["uart"],
"Project Type": ["sensor"],
"Manufacturers": ["Omron"],
"Image": "",
"Examples": {
"C++": ["omron2jciebu01_usb.cxx"]
},
"Specifications": {
"Baud Rate": {
"unit" : "bps",
"default": 115200
}
},
"Platforms": {
"Intel Edison": {
"Notes": ["Might need USB type omron enviroment sensor"]
}
},
"Urls": {
"Product Pages": ["https://www.components.omron.com/solutions/mems-sensors/environment-sensor"],
"Datasheets": ["https://omronfs.omron.com/en_US/ecb/products/pdf/A279-E1-01.pdf"]
}
}
}
}
{
"Library": "2jciebu01_usb",
"Description": "Omron USB type enviroment sensor",
"Sensor Class": {
"OM2JCIEBU_UART": {
"Name": "API for 2JCIEBU01 Sensor Module using USB to UART interface",
"Description": "This is the UPM Module for the Omron Enviroment Sensor Module using USB to UART interface.",
"Aliases": [""],
"Categories": ["USB"],
"Connections": ["uart"],
"Project Type": ["sensor"],
"Manufacturers": ["Omron"],
"Image": "",
"Examples": {
"C++": ["omron2jciebu01_usb.cxx"]
},
"Specifications": {
"Baud Rate": {
"unit" : "bps",
"default": 115200
}
},
"Platforms": {
"Intel Edison": {
"Notes": ["Might need USB type omron enviroment sensor"]
}
},
"Urls": {
"Product Pages": ["https://www.components.omron.com/solutions/mems-sensors/environment-sensor"],
"Datasheets": ["https://omronfs.omron.com/en_US/ecb/products/pdf/A279-E1-01.pdf"]
}
}
}
}

10
Omron_2jcie-bu01_usb/upm/src/2jciebu01-usb/CMakeLists.txt → src/2jciebu01-usb/CMakeLists.txt
View File

@ -1,5 +1,5 @@
set (libname "2jciebu01_usb")
set (libdescription "Omron Environment Sensor")
set (module_src ${libname}.cxx "2jciebu01.cxx")
set (module_hpp ${libname}.hpp "2jciebu01.hpp")
upm_module_init(mraa utilities-c)
set (libname "2jciebu01_usb")
set (libdescription "Omron Environment Sensor")
set (module_src ${libname}.cxx "2jciebu01.cxx")
set (module_hpp ${libname}.hpp "2jciebu01.hpp")
upm_module_init(mraa utilities-c)