The actual allowed values may vary by chip. Check the datasheet and/or RadioLib documentation.
#
#### ```#define LORA_FREQUENCY n```
#### `#define LORA_FREQUENCY n`
LoRa frequency in MHz. Allowed values range from 137.0 MHz to 1020.0 MHz.
#### ```#define LORA_SF n```
#### `#define LORA_SF n`
LoRa spreading factor. Allowed values range from 6 to 12.
#### ```#define LORA_BANDWIDTH n```
#### `#define LORA_BANDWIDTH n`
LoRa bandwidth in kHz. Allowed values are 10.4, 15.6, 20.8, 31.25, 41.7, 62.5, 125, 250 and 500 kHz.
#### ```#define LORA_CR n```
#### `#define LORA_CR n`
LoRa coding rate denominator. Allowed values range from 5 to 8.
#### ```#define LORA_SYNCWORD n```
#### `#define LORA_SYNCWORD n`
LoRa sync word. Can be used to distinguish different networks. Note that 0x34 is reserved for LoRaWAN.
#### ```#define LORA_INTERVAL n```
#### `#define LORA_INTERVAL n`
Interval between LoRa buffer releases. Must be longer than transmission time-on-air.
## WiFi and MQTT Configuration
WiFi and MQTT parameters are generally configured in the 'src/fdrs_globals.h' file. Be sure to use the correct topic when sending MQTT commands. The following values may be set in the gateway configuration file if the user wishes to override the global value:
#### ```#define WIFI_SSID "cccc"``` and ``` WIFI_PASS "cccc" ```
#### `#define WIFI_SSID "cccc"` and ` WIFI_PASS "cccc" `
WiFi credentials
#### ```#define MQTT_ADDR "n.n.n.n"``` or ```MQTT_ADDR "cccc"```
#### `#define MQTT_ADDR "n.n.n.n"` or `MQTT_ADDR "cccc"`
The address of the MQTT server, either the IP address or domain name.
#### ```#define MQTT_PORT n ```
#### `#define MQTT_PORT n `
The port of the MQTT server.
#### ```#define MQTT_AUTH ```
#### `#define MQTT_AUTH `
Enable this if using MQTT authentication
#### ```#define MQTT_USER "cccc"``` and ```MQTT_PASS "cccc"```
#### `#define MQTT_USER "cccc"` and `MQTT_PASS "cccc"`
#
### SSD1306 OLED Display
Built on the [ThingPulse OLED SSD1306 Library](https://github.com/ThingPulse/esp8266-oled-ssd1306)
#### ```#define OLED_HEADER "cccc"```
#### `#define OLED_HEADER "cccc"`
The message to be displayed at the top of the screen.
#### ```#define OLED_SDA n``` and ```OLED_SCL n```
#### `#define OLED_SDA n` and `OLED_SCL n`
OLED I²C pins.
#### ```#define OLED_RST n```
#### `#define OLED_RST n`
OLED reset pin. Use '-1' if not present or known.
#
### Miscellaneous
#### ```#define FDRS_DEBUG```
#### `#define FDRS_DEBUG`
Enables debugging messages to be sent over the serial port and OLED display.
#### ```#define RXD2 (pin)``` and ```TXD2 (pin)```
#### `#define DBG_LEVEL n`
Sets the level of verbosity in debug messages. '0' (default) shows only the most important system messages, '1' will show additional debug messages for troubleshooting, and '2' will show all messages, including those used in development. Much gratitude to [Jeff Lehman](https://github.com/aviateur17) for this feature!
#### `#define RXD2 (pin)` and `TXD2 (pin)`
Configures a second, data-only UART interface on ESP32. The ESP8266 serial interface is not configurable, and thus these options don't apply.
#### ```#define USE_LR```
#### `#define USE_LR`
Enables ESP-NOW Long-Range mode. Requires ESP32.
## User-Defined Functions
This feature allows the user to send data from the gateway itself. For example: the battery level or ambient temperature at the gateway.
Calling ```scheduleFDRS(function, interval);``` after initializing FDRS will schedule ```function()``` to be called every ```interval``` milliseconds.
Calling `scheduleFDRS(function, interval);` after initializing FDRS will schedule `function()` to be called every `interval` milliseconds.
Within this function, the user may utilize the same ```loadFDRS()``` and ```sendFDRS()``` commands used by sensors. After the data is sent, it triggers ```INTERNAL_ACT``` where it can be routed to the front-end.
Within this function, the user may utilize the same `loadFDRS()` and `sendFDRS()` commands used by sensors. After the data is sent, it triggers `INTERNAL_ACT` where it can be routed to the front-end.
A node is a device that sends and receives data from a nearby gateway. A node can be a **sensor**, **controller**, ***or both***.
## Addresses
#### ```#define READING_ID n```
The unique ID that the node will use when sending sensor values. Can be any integer 0 - 65535. Nodes are not necessarily tied to this parameter. They can be subscribed to up to 256 different IDs or send using several different IDs.
#### ```#define GTWY_MAC 0xnn```
The ```UNIT_MAC``` of the gateway that this device will be paired with.
## Usage
#### ```beginFDRS();```
Initializes FDRS, powers up the sensor array, and begins ESP-NOW and/or LoRa.
#### ```uint32_t pingFDRS(timeout);```
Sends a ping request to the device's paired gateway with a timeout in ms. Returns the ping time in ms as well as displaying it on the debugging console.
Loads some data into the current packet. 'data' is a float, 'type' is the data type (see below), and 'id' is the DataReading id.
#### ```loadFDRS((float data, uint8_t type);```
Same as above, but the 'id' is preset to the node's ```READING_ID```.
#### ```bool sendFDRS();```
Sends the current packet using ESP-NOW and/or LoRa. Returns true if packet is confirmed to have been recieved successfully by the gateway.
#### ```sleepFDRS(seconds)```
Time to sleep in seconds. If ```DEEP_SLEEP``` is enabled, the device will enter sleep. Otherwise it will use a simple ```delay()```.
## Controller API
#### ```addFDRS(void callback);```
Initializes controller functionality by selecting the function to be called when incoming commands are recieved. If using LoRa, the controller will automatically recieve any packets sent with broadcastLoRa(), provided they were sent by the paired gateway. ESP-NOW requires the device to register with its gateway before it will recieve incoming commands. This is done automatically, and the ESP-NOW node will continue recieving data until the paired gateway is reset. A maximum of 16 ESP-NOW controllers can recieve data from a single gateway. There is no limit to how many LoRa controllers can listen to the same gateway.
#### ```subscribeFDRS(uint16_t sub_id);```
Sets the device to listen for a specific DataReading id. When a DataReading with id ```sub_id``` is received, the callback function will be called and given the full DataReading as a parameter.
#### ```unsubscribeFDRS(uint16_t sub_id);```
Removes ```sub_id``` from subscription list.
#### ```loopFDRS();```
Always add this to ```loop()``` to handle the controller's listening capabilities.
A node is a device that sends and receives data from a nearby gateway. This is where the user can communicate with a network of FDRS gateways using their own sketch. A node can be a **sensor** (sending data), **controller** (receiving data), ***or both***.
addFDRS(fdrs_recv_cb); // Call fdrs_recv_cb() when data arrives.
subscribeFDRS(READING_ID); // Subscribe to DataReadings with ID matching READING_ID
subscribeFDRS(42); // Subscribe to DataReadings with ID 42
}
void loop() {
loopFDRS(); // Listen for data
}
```
## Addresses
#### `#define READING_ID n`
The unique ID that the node will use when sending sensor values. Can be any integer 0 - 65535. Nodes are not necessarily tied to this parameter. They can be subscribed to up to 256 different IDs or send using several different IDs.
#### `#define GTWY_MAC 0xnn`
The `UNIT_MAC` of the gateway that this device will be paired with.
## Usage
#### `beginFDRS();`
Initializes FDRS, powers up the sensor array, and begins ESP-NOW and/or LoRa.
#### `uint32_t pingFDRS(timeout);`
Sends a ping request to the device's paired gateway with a timeout in ms. Returns the ping time in ms and displays it on the debugging console.
Loads some data into the current packet. 'data' is a float, 'type' is the data type (see below), and 'id' is the DataReading id.
#### `loadFDRS((float data, uint8_t type);`
Same as above, but the 'id' is preset to the node's `READING_ID`.
#### `bool sendFDRS();`
Sends the current packet using ESP-NOW and/or LoRa. Returns true if packet is confirmed to have been recieved successfully by the gateway.
#### `sleepFDRS(seconds)`
Time to sleep in seconds. If ```DEEP_SLEEP``` is enabled, the device will enter sleep. Otherwise it will use a simple ```delay()```.
## Controller API
#### ```addFDRS(void callback);```
Initializes controller functionality by selecting the function to be called when incoming commands are recieved. If using LoRa, the controller will automatically recieve any packets sent with broadcastLoRa(), provided they were sent by the paired gateway. ESP-NOW requires the device to register with its gateway before it will recieve incoming commands. This is done automatically, and the ESP-NOW node will continue recieving data until the paired gateway is reset. A maximum of 16 ESP-NOW controllers can recieve data from a single gateway. There is no limit to how many LoRa controllers can listen to the same gateway.
#### ```subscribeFDRS(uint16_t sub_id);```
Sets the device to listen for a specific DataReading id. When a DataReading with id ```sub_id``` is received, the callback function will be called and given the full DataReading as a parameter.
#### ```unsubscribeFDRS(uint16_t sub_id);```
Removes ```sub_id``` from subscription list.
#### ```loopFDRS();```
Always add this to ```loop()``` to handle the controller's listening capabilities.
## Configuration
#### ```#define USE_ESPNOW```
#### `#define USE_ESPNOW`
Enables/disables ESP-NOW.
#### ```#define USE_LORA```
#### `#define USE_LORA`
Enables/disables LoRa.
#### ```#define LORA_ACK```
Enables LoRa packet acknowledgement. The device will use CRC to ensure that the data arrived at its destination correctly. If disabled, ```sendFDRS()``` will always return true when sending LoRa packets.
Thanks to [aviateur17](https://github.com/aviateur17) for this feature!
#### ```#define FDRS_DEBUG```
#### `#define FDRS_DEBUG`
This definition enables debug messages to be sent over the serial port. If disabled, no serial debug interface will be initialized.
#### ```#define DEEP_SLEEP```
#### `#define DBG_LEVEL n`
Sets the level of verbosity in debug messages. '0' (default) shows only the most important system messages, '1' will show additional debug messages for troubleshooting, and '2' will show all messages, including those used in development. Much gratitude to [Jeff Lehman](https://github.com/aviateur17) for this feature!
#### `#define DEEP_SLEEP`
If enabled, device will enter deep-sleep when the sleepFDRS() command is used. If using ESP8266, be sure that you connect the WAKE pin (GPIO 16) to RST or your device will not wake up.
#### ```#define POWER_CTRL n```
#### `#define POWER_CTRL n`
If defined, power control will bring a GPIO pin high when FDRS is initialized. This is useful for powering sensors while running on battery.
#
## LoRa Configuration
#### ```#define RADIOLIB_MODULE cccc```
#### ```#define LORA_ACK```
Enables LoRa packet acknowledgement. The device will use CRC to ensure that the data arrived at its destination correctly. If disabled, ```sendFDRS()``` will always return true when sending LoRa packets.
Thanks [Jeff Lehman](https://github.com/aviateur17) for this feature!
#### `#define RADIOLIB_MODULE cccc`
The name of the RadioLib module being used. Tested modules: SX1276, SX1278, SX1262.
#### ```#define LORA_SS n```
#### `#define LORA_SS n`
LoRa chip select pin.
#### ```#define LORA_RST n```
#### `#define LORA_RST n`
LoRa reset pin.
#### ```#define LORA_DIO n```
#### `#define LORA_DIO n`
LoRa DIO pin. This refers to DIO1 on SX127x chips and DIO1 on SX126x chips.
#### ```#define LORA_BUSY n```
#### `#define LORA_BUSY n`
For SX126x chips: LoRa BUSY pin. For SX127x: DIO1 pin, or "RADIOLIB_NC" to leave it blank.
#### ```#define LORA_TXPWR n```
#### `#define LORA_TXPWR n`
LoRa TX power in dBm.
#### ```#define USE_SX126X```
#### `#define USE_SX126X`
Enable this if using the SX126x series of LoRa chips.
#
### SSD1306 OLED Display
Built on the [ThingPulse OLED SSD1306 Library](https://github.com/ThingPulse/esp8266-oled-ssd1306)
##### ```#define OLED_HEADER "cccc"```
##### `#define OLED_HEADER "cccc"`
The message to be displayed at the top of the screen.
#### ```#define OLED_SDA n``` and ```OLED_SCL n```