Pubnub demo for AT&T IoT Starter Kit. Functionally similar to the Flow demo.
Dependencies: FXOS8700CQ MODSERIAL mbed
Pubnub demo for AT&T IoT Starter Kit
This demo is functionally similar to the Flow demo, so you can find general information here: https://developer.mbed.org/users/JMF/code/Avnet_ATT_Cellular_IOT/.
The only difference is that we use Pubnub to publish the measurements and subscribe to receiving the instructions to set the LED.
Settings
Pubnub related settings are:
Pubnub settings in `config_me.h`
PUBNUB_SUBSCRIBE_KEY PUBNUB_PUBLISH_KEY PUBNUB_CHANNEL
All are documented in their respective comments.
Pubnub context class
Similar to Pubnub SDKs, we provide a Pubnub context class. It is defined in pubnub.h
header file and implemented in pubnub.cpp
.
It provides only the fundamental "publish" and "subscribe" methods. They are documented in the header file.
This class is reusable in other code (it is not specific to this demo), it has a very narrow interface to the AT&T IoT cellular modem code. For example of use, you can look at the main()
(in main.c
).
Sample of published data
Published message w/measurement data
{"serial":"vstarterkit001","temp":89.61,"humidity":35,"accelX":0.97,"accelY":0.013,"accelZ":-0.038}
Don't worry, nobody got burnt, the temperature is in degrees Fahrenheit. :)
Publish a message (from, say, the Pubnub console http://pubnub.com/console) of the form {"LED":<name-of-the-color>}
on the channel that this demo listens to (default is hello_world
) to turn the LED to that color on the Starter Kit:
Turn LED to red
{"LED":"Red"}
Turn LED to green
{"LED":"Green"}
Turn LED to blue
{"LED":"Blue"}
xadow_gps.cpp
- Committer:
- sveljko
- Date:
- 2016-09-02
- Revision:
- 81:a5df87708b9a
- Parent:
- 69:5a3414cc7531
File content as of revision 81:a5df87708b9a:
/* =================================================================== Copyright © 2016, AVNET Inc. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. ======================================================================== */ #include "mbed.h" #include "xadow_gps.h" #include "hardware.h" // Xadow code based on Eclipse test project at // https://github.com/WayenWeng/Xadow_GPS_v2_test/ // These first 3 routines are to allow the mbed I2C to be used instead of what was in the Eclipse test code void dlc_i2c_configure(int slave_addr, int speed) { } //dlc_i2c_configure unsigned char dlc_i2c_receive_byte(void) { char rxbuffer [1]; i2c.read(GPS_DEVICE_ADDR, rxbuffer, 1 ); return (unsigned char)rxbuffer[0]; } //dlc_i2c_receive_byte() unsigned char dlc_i2c_send_byte(unsigned char ucData) { int status; char txbuffer [1]; txbuffer[0] = (char)ucData; status = i2c.write(GPS_DEVICE_ADDR, txbuffer, 1, false); //true: do not send stop return status; } //dlc_i2c_send_byte() unsigned char gps_check_online(void) { unsigned char data[GPS_SCAN_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_SCAN_ID); for(i=0;i<(GPS_SCAN_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } if(data[5] == GPS_DEVICE_ID) return 1; else return 0; } unsigned char gps_utc_date_time[GPS_UTC_DATE_TIME_SIZE] = {0}; unsigned char* gps_get_utc_date_time(void) { unsigned char data[GPS_UTC_DATE_TIME_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_UTC_DATE_TIME_ID); for(i=0;i<(GPS_UTC_DATE_TIME_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } for(i=0;i<GPS_UTC_DATE_TIME_SIZE;i++) gps_utc_date_time[i] = data[i+2]; return gps_utc_date_time; } unsigned char gps_get_status(void) { unsigned char data[GPS_STATUS_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_STATUS_ID); for(i=0;i<(GPS_STATUS_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } return data[2]; } float gps_get_latitude(void) { char data[GPS_LATITUDE_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_LATITUDE_ID); for(i=0;i<(GPS_LATITUDE_SIZE+2);i++) { data[i] = (char)dlc_i2c_receive_byte(); } return atof(&data[2]); } unsigned char gps_get_ns(void) { unsigned char data[GPS_NS_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_NS_ID); for(i=0;i<(GPS_NS_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } if(data[2] == 'N' || data[2] == 'S')return data[2]; else return data[2] = '-'; } float gps_get_longitude(void) { char data[GPS_LONGITUDE_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_LONGITUDE_ID); for(i=0;i<(GPS_LONGITUDE_SIZE+2);i++) { data[i] = (char)dlc_i2c_receive_byte(); } return atof(&data[2]); } unsigned char gps_get_ew(void) { unsigned char data[GPS_EW_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_EW_ID); for(i=0;i<(GPS_EW_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } if(data[2] == 'E' || data[2] == 'W')return data[2]; else return data[2] = '-'; } float gps_get_speed(void) { char data[GPS_SPEED_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_SPEED_ID); for(i=0;i<(GPS_SPEED_SIZE+2);i++) { data[i] = (char)dlc_i2c_receive_byte(); } return atof(&data[2]); } float gps_get_course(void) { char data[GPS_COURSE_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_COURSE_ID); for(i=0;i<(GPS_COURSE_SIZE+2);i++) { data[i] = (char)dlc_i2c_receive_byte(); } return atof(&data[2]); } unsigned char gps_get_position_fix(void) { unsigned char data[GPS_POSITION_FIX_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_POSITION_FIX_ID); for(i=0;i<(GPS_POSITION_FIX_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } return data[2]; } unsigned char gps_get_sate_used(void) { unsigned char data[GPS_SATE_USED_SIZE+2]; unsigned char i; unsigned char value; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_SATE_USED_ID); for(i=0;i<(GPS_SATE_USED_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } if(data[3] >= '0' && data[3] <= '9')value = (data[3] - '0') * 10; else value = 0; if(data[2] >= '0' && data[2] <= '9')value += (data[2] - '0'); else value += 0; return value; } float gps_get_altitude(void) { char data[GPS_ALTITUDE_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_ALTITUDE_ID); for(i=0;i<(GPS_ALTITUDE_SIZE+2);i++) { data[i] = (char)dlc_i2c_receive_byte(); } return atof(&data[2]); } unsigned char gps_get_mode(void) { unsigned char data[GPS_MODE_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_MODE_ID); for(i=0;i<(GPS_MODE_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } return data[2]; } unsigned char gps_get_mode2(void) { unsigned char data[GPS_MODE2_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_MODE2_ID); for(i=0;i<(GPS_MODE2_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } return data[2]; } unsigned char gps_get_sate_in_veiw(void) { unsigned char data[GPS_SATE_IN_VIEW_SIZE+2]; unsigned char i; dlc_i2c_configure(GPS_DEVICE_ADDR, 100); dlc_i2c_send_byte(GPS_SATE_IN_VIEW_ID); for(i=0;i<(GPS_SATE_IN_VIEW_SIZE+2);i++) { data[i] = dlc_i2c_receive_byte(); } return data[2]; }