This repository contains the IBM LMIC (LoRaWAN-MAC-in-C) library, slightly modified to run in the Arduino environment, allowing using the SX1272, SX1276 transceivers and compatible modules (such as some HopeRF RFM9x modules and the Murata LoRa modules).
This library mostly exposes the functions defined by LMIC, it makes no attempt to wrap them in a higher level API that is more in the Arduino style. To find out how to use the library itself, see the examples, or see the PDF file in the doc subdirectory.
The MCCI arduino-lorawan
library provides a higher level, more Arduino-like wrapper which may be useful.
This library requires Arduino IDE version 1.6.6 or above, since it requires C99 mode to be enabled by default.
Contents:
- Installing
- Features
- Additional Documentation
- Configuration
- Selecting the LoRaWAN Version
- Selecting the LoRaWAN Region Configuration
- Selecting the target radio transceiver
- Controlling use of interrupts
- Disabling PING
- Disabling Beacons
- Enabling Network Time Support
- Rarely changed variables
- Changing debug output
- Getting debug from the RF library
- Selecting the AES library
- Defining the OS Tick Frequency
- Setting the SPI-bus frequency
- Changing handling of runtime assertion failures
- Disabling JOIN
- Disabling Class A MAC commands
- Disabling Class B MAC commands
- Disabling user events
- Disabling external reference to
onEvent()
- Enabling long messages
- Enabling LMIC event logging calls
- Special purpose
- Supported hardware
- Pre-Integrated Boards
- PlatformIO
- Manual configuration
- Example Sketches
- Timing
- Downlink data rate
- Encoding Utilities
- Release History
- Contributions
- Trademark Acknowledgements
- License
To install this library:
- install it using the Arduino Library manager ("Sketch" -> "Include Library" -> "Manage Libraries..."), or
- download a zip file from GitHub using the "Download ZIP" button and install it using the IDE ("Sketch" -> "Include Library" -> "Add .ZIP Library..."
- clone this git repository into your sketchbook/libraries folder.
For more info, see https://www.arduino.cc/en/Guide/Libraries.
The LMIC library provides a fairly complete LoRaWAN Class A and Class B implementation, supporting the EU-868, US-915, AU-921, AS-923, and IN-866 bands. Only a limited number of features was tested using this port on Arduino hardware, so be careful when using any of the untested features.
The library has only been tested with LoRaWAN 1.0.2/1.03 networks and does not have the separated key structure defined by LoRaWAN 1.1.
What certainly works:
- Sending packets uplink, taking into account duty cycling.
- Encryption and message integrity checking.
- Custom frequencies and data rate settings.
- Over-the-air activation (OTAA / joining).
- Receiving downlink packets in the RX1 and RX2 windows.
- MAC command processing.
What has not been tested:
- Class B operation.
- FSK has not been extensively tested. (Testing with the RedwoodComm RWC5020A analyzer in 2019 indicated that FSK downlink is stable but not reliable. This prevents successful completion of LoRaWAN pre-certification in regions that require support for FSK.)
If you try one of these untested features and it works, be sure to let us know (creating a GitHub issue is probably the best way for that).
The doc
directory contains LMIC-v3.0.99.pdf, which documents the library APIs and use. It's based on the original IBM documentation, but has been adapted for this version of the library. However, as this library is used for more than Arduino, that document is supplemented by practical details in this document.
There is a general framework for adding support for a new region. HOWTO-ADD-REGION.md has step-by-step instructions for adding a region.
See the list of bugs at mcci-catena/arduino-lmic
.
The LoRaWAN technology for class A devices requires devices to meet hard real-time deadlines. The Arduino environment doesn't provide built-in support for this, and this port of the LMIC doesn't really ensure it, either. It is your responsibility, when constructing your application, to ensure that you call os_runloop_once()
"often enough".
How often is often enough?
It depends on what the LMIC is doing. For Class A devices, when the LMIC is idle, os_runloop_once()
need not be called at all. However, during a message transmit, it's critical to ensure that os_runloop_once()
is called frequently prior to hard deadlines. The API os_queryTimeCriticalJobs()
can be used to check whether there are any deadlines due soon. Before doing work that takes n
milliseconds, call os_queryTimeCriticalJobs(ms2osticks(n))
, and skip the work if the API indicates that the LMIC needs attention.
However, in the current implementation, the LMIC is tracking the completion of uplink transmits. This is done by checking for transmit-complete indications, which is done by polling. So you must also continually call os_runloop_once()
while waiting for a transmit to be completed. This is an area for future improvement.
The Board Support Package V2.5.0 for the MCCI Murata-based boards (MCCI Catena 4610, MCCI Catena 4612, etc.) has a defect in clock calibration that prevents the compliance script from being used without modification. Versions V2.6.0 and later solve this issue.
The LMIC has a simple event notification system. When an interesting event occurs, it calls a user-provided function.
This function is sometimes called at time critical moments.
This means that your event function should avoid doing any time-critical work.
Furthermore, in versions of the LMIC prior to v3.0.99.3, the event function may be called in situations where it's not safe to call the general LMIC APIs. In those older LMIC versions, please be careful to defer all work from your event function to your loop()
function. See the compliance example sketch for an elaborate version of how this can be done.
A number of features can be enabled or disabled at compile time.
This is done by adding the desired settings to the file
project_config/lmic_project_config.h
. The project_config
directory is the only directory that contains files that you
should edit to match your project; we organize things this way
so that your local changes are more clearly separated from
the distribution files. The Arduino environment doesn't give
us a better way to do this, unless you change BOARDS.txt
.
Unlike other ports of the LMIC code, in this port, you should not edit src/lmic/config.h
to configure this package. The intention is that you'll edit the project_config/lmic_project_config.h
(if using the Arduino environment), or change compiler command-line input (if using PlatformIO, make, etc.).
The following configuration variables are available.
This library implements V1.0.3 of the LoRaWAN specification. However, it can also be used with V1.0.2. The only significant change when selecting V1.0.2 is that the US accepted power range in MAC commands is 10 dBm to 30 dBm; whereas in V1.0.3 the accepted range 2 dBm to 30 dBm.
The default LoRaWAN version, if no version is explicitly selected, is V1.0.3.
LMIC_LORAWAN_SPEC_VERSION
is defined as an integer reflecting the targeted spec version; it will be set to LMIC_LORAWAN_SPEC_VERSION_1_0_2
or LMIC_LORAWAN_SPEC_VERSION_1_0_3
. Arithmetic comparisons can be done on these version numbers: and we guarantee LMIC_LORAWAN_SPEC_VERSION_1_0_3 > LMIC_LORAWAN_SPEC_VERSION_1_0_2
, but the details of the how the versions are encoded may change, and your code should not rely upon the details.
In project_config/lmic_project_config.h
, add:
#define LMIC_LORAWAN_SPEC_VERSION LMIC_LORAWAN_SPEC_VERSION_1_0_2
On your compiler command line, add:
-D LMIC_LORAWAN_SPEC_VERSION=LMIC_LORAWAN_SPEC_VERSION_1_0_2
In project_config/lmic_project_config.h
, add:
#define LMIC_LORAWAN_SPEC_VERSION LMIC_LORAWAN_SPEC_VERSION_1_0_3
On your compiler command line, add:
-D LMIC_LORAWAN_SPEC_VERSION=LMIC_LORAWAN_SPEC_VERSION_1_0_3
This is the default.
The library supports the following regions:
-D variable |
CFG region name | CFG region value | LoRaWAN Regional Spec 1.0.3 Reference | Frequency |
---|---|---|---|---|
-D CFG_eu868 |
LMIC_REGION_eu868 |
1 | 2.2 | EU 863-870 MHz ISM |
-D CFG_us915 |
LMIC_REGION_us915 |
2 | 2.3 | US 902-928 MHz ISM |
-D CFG_au915 |
LMIC_REGION_au915 |
5 | 2.6 | Australia 915-928 MHz ISM |
-D CFG_as923 |
LMIC_REGION_as923 |
7 | 2.8 | Asia 923 MHz ISM |
-D CFG_as923jp |
LMIC_REGION_as923 and LMIC_COUNTRY_CODE_JP |
7 | 2.8 | Asia 923 MHz ISM with Japan listen-before-talk (LBT) rules |
-D CFG_kr920 |
LMIC_REGION_kr920 |
8 | 2.9 | Korea 920-923 MHz ISM |
-D CFG_in866 |
LMIC_REGION_in866 |
9 | 2.10 | India 865-867 MHz ISM |
The library requires that the compile environment or the project config file define exactly one of CFG_...
variables. As released, project_config/lmic_project_config.h
defines CFG_us915
. If you build with PlatformIO or other environments, and you do not provide a pointer to the platform config file, src/lmic/config.h
will define CFG_eu868
.
MCCI BSPs add menu entries to the Arduino IDE so you can select the target region interactively.
The library changes configuration pretty substantially according to the region selected, and this affects the symbols in-scope in your sketches and .cpp
files. Some of the differences are listed below. This list is not comprehensive, and is subject to change in future major releases.
If the library is configured for EU868, AS923, or IN866 operation, we make the following changes:
- Add the API
LMIC_setupBand()
. - Add the constants
MAX_CHANNELS
,MAX_BANDS
,LIMIT_CHANNELS
,BAND_MILLI
,BAND_CENTI
,BAND_DECI
, andBAND_AUX
.
If the library is configured for US915 operation, we make the following changes:
- Add the APIs
LMIC_enableChannel()
,LMIC_enableSubBand()
,LMIC_disableSubBand()
, andLMIC_selectSubBand()
. - Add the constants
MAX_XCHANNELS
. - Add a number of additional
DR_...
symbols.
You should define one of the following variables. If you don't, the library assumes sx1276. There is a runtime check to make sure the actual transceiver matches the library configuration.
#define CFG_sx1272_radio 1
Configures the library for use with an sx1272 transceiver.
#define CFG_sx1276_radio 1
Configures the library for use with an sx1276 transceiver.
#define LMIC_USE_INTERRUPTS
If defined, configures the library to use interrupts for detecting events from the transceiver. If left undefined, the library will poll for events from the transceiver. See Timing for more info.
#define DISABLE_PING
If defined, removes all code needed for Class B downlink during ping slots (PING). Removes the APIs LMIC_setPingable()
and LMIC_stopPingable()
.
Class A devices don't support PING, so defining DISABLE_PING
is often a good idea.
By default, PING support is included in the library.
#define DISABLE_BEACONS
If defined, removes all code needed for handling beacons. Removes the APIs LMIC_enableTracking()
and LMIC_disableTracking()
.
Enabling beacon handling allows tracking of network time, and is required if you want to enable downlink during ping slots. However, many networks don't support Class B devices. Class A devices don't support tracking beacons, so defining DISABLE_BEACONS
might be a good idea.
By default, beacon support is included in the library.
#define LMIC_ENABLE_DeviceTimeReq number /* boolean: 0 or non-zero */
Disable or enable support for device network-time requests (LoRaWAN MAC request 0x0D). If zero, support is disabled. If non-zero, support is enabled.
If disabled, stub routines are provided that will return failure (so you don't need conditional compiles in client code).
The remaining variables are rarely used, but we list them here for completeness.
#define LMIC_PRINTF_TO SerialLikeObject
This variable should be set to the name of a Serial
-like object, used for printing messages. If not defined, Serial
is assumed.
#define LMIC_DEBUG_LEVEL number /* 0, 1, or 2 */
This variable determines the amount of debug output to be produced by the library. The default is 0
.
If LMIC_DEBUG_LEVEL
is zero, no output is produced. If 1
, limited output is produced. If 2
, more extensive
output is produced. If non-zero, printf()
is used, and the Arduino environment must be configured to support it,
otherwise the sketch will crash at runtime.
The library comes with two AES implementations. The original implementation is better on ARM processors because it's faster, but it's larger. For smaller AVR8 processors, a second library ("IDEETRON") is provided that has a smaller code footprint. You may define one of the following variables to choose the AES implementation. If you don't, the library uses the IDEETRON version.
#define USE_ORIGINAL_AES
If defined, the original AES implementation is used.
#define USE_IDEETRON_AES
If defined, the IDEETRON AES implementation is used.
#define US_PER_OSTICK_EXPONENT number
This variable should be set to the base-2 logarithm of the number of microseconds per OS tick. The default is 4, which indicates that each tick corresponds to 16 microseconds (because 16 == 2^4).
#define LMIC_SPI_FREQ floatNumber
This variable sets the default frequency for the SPI bus connection to the transceiver. The default is 1E6
, meaning 1 MHz. However, this can be overridden by the contents of the lmic_pinmap
structure, and we recommend that you use that approach rather than editing the project_config/lmic_project_config.h
file.
The variables LMIC_FAILURE_TO
and DISABLE_LMIC_FAILURE_TO
control the handling of runtime assertion failures. By default, assertion messages are displayed using
the Serial
object. You can define LMIC_FAILURE_TO to be the name of some other Print
-like object. You can
also define DISABLE_LMIC_FAILURE_TO
to any value, in which case assert failures will silently halt execution.
#define DISABLE_JOIN
If defined, removes code needed for OTAA activation. Removes the APIs LMIC_startJoining()
and LMIC_tryRejoin()
.
DISABLE_MCMD_DutyCycleReq
, DISABLE_MCMD_RXParamSetupReq
, DISABLE_MCMD_RXTimingSetupReq
, DISABLE_MCMD_NewChannelReq
, and DISABLE_MCMD_DlChannelReq
respectively disable code for various Class A MAC commands.
DISABLE_MCMD_PingSlotChannelReq
disables the PING_SET MAC commands. It's implied by DISABLE_PING
.
ENABLE_MCMD_BeaconTimingAns
enables the next-beacon start command. It's disabled by default, and overridden (if enabled) by DISABLE_BEACON
. (This command is deprecated.)
Code to handle registered callbacks for transmit, receive, and events can be suppressed by setting LMIC_ENABLE_user_events
to zero. This C preprocessor macro is always defined as a post-condition of #include "config.h"
; if non-zero, user events are supported, if zero, user events are not-supported. The default is to support user events.
In V3 of the LMIC, you do not need to define a function named onEvent
. The LMIC will notice that there's no such function, and will suppress the call. However, be cautious -- in a large software package, onEvent()
may be defined for some other purpose. The LMIC has no way of knowing that this is not the LMIC's onEvent
, so it will call the function, and this may cause problems.
All reference to onEvent()
can be suppressed by setting LMIC_ENABLE_onEvent
to 0. This C preprocessor macro is always defined as a post-condition of #include "config.h"
; if non-zero, a weak reference to onEvent()
will be used; if zero, the user onEvent()
function is not supported, and the client must register an event handler explicitly. See the PDF documentation for details on LMIC_registerEventCb()
.
To save RAM for simple devices, the LMIC allows message length to be limited to 64 bytes instead of the LoRaWAN standard of 255 bytes max. This saves about 2*192 bytes of RAM. Unfortunately, compliance tests require the full message size. Long messages are enabled by setting LMIC_ENABLE_long_messages
to 1, or disabled by setting it to zero. This C preprocessor macro is always defined as a post-condition of #include "config.h"
; if non-zero, the maximum frame size is 255 bytes, and if zero, the maximum frame size is 64 bytes.
When debugging the LMIC, debug prints change timing, and can make things not work at all. The LMIC has embedded optional calls to capture debug information that can be printed out later, when the LMIC is not active. Logging is enabled by setting LMIC_ENABLE_event_logging
to 1. The default is not to log. This C preprocessor macro is always defined as a post-condition of #include "config.h"
.
The compliance test script includes a suitable logging implementation; the other example scripts do not.
#define DISABLE_INVERT_IQ_ON_RX
disables the inverted Q-I polarity on RX. Use of this variable is deprecated, see issue #250. Rather than defining this, set the value of LMIC.noRXIQinversion
. If set non-zero, receive will be non-inverted. End-devices will be able to receive messages from each other, but will not be able to hear the gateway (other than Class B beacons)aa. If set zero, (the default), end devices will only be able to hear gateways, not each other.
This library is intended to be used with plain LoRa transceivers, connecting to them using SPI. In particular, the SX1272 and SX1276 families are supported (which should include SX1273, SX1277, SX1278 and SX1279 which only differ in the available frequencies, bandwidths and spreading factors). It has been tested with both SX1272 and SX1276 chips, using the Semtech SX1272 evaluation board and the HopeRF RFM92 and RFM95 boards (which supposedly contain an SX1272 and SX1276 chip respectively).
This library contains a full LoRaWAN stack and is intended to drive these Transceivers directly. It is not intended to be used with full-stack devices like the Microchip RN2483 and the Embit LR1272E. These contain a transceiver and microcontroller that implements the LoRaWAN stack and exposes a high-level serial interface instead of the low-level SPI transceiver interface.
This library is intended to be used inside the Arduino environment. It should be architecture-independent. Users have tested this on AVR, ARM, Xtensa-based, and RISC-V based system.
This library can be quite heavy on small systems, especially if the fairly small ATmega
328p (such as in the Arduino Uno) is used. In the default configuration,
the available 32K flash space is nearly filled up (this includes some
debug output overhead, though). By disabling some features in project_config/lmic_project_config.h
(like beacon tracking and ping slots, which are not needed for Class A devices),
some space can be freed up.
There are two ways of using this library, either with pre-integrated boards or with manually configured boards.
The following boards are pre-integrated.
- Adafruit Feather 32u4 LoRa 900 MHz (SX1276)
- Adafruit Feather M0 LoRa 900 MHz (SX1276)
- MCCI Catena 4410, 4420, 4450, 4460 and 4470 boards (based on Adafruit Feather boards plus wings) (SX1276)
- MCCI Catena 4551, 4610, 4611, 4612, 4617, 4618, 4630, and 4801 boards (based on the Murata CMWX1ZZABZ-078 module) (SX1276)
- TTGo LoRa32 V1 (based on the ESP32)
- Heltec WiFi LoRa 32 V2 (based on the ESP32)
To help you know if you have to worry, we'll call such boards "pre-integrated" and prefix each section with suitable guidance.
For use with PlatformIO, the lmic_project_config.h
has to be disabled with the flag ARDUINO_LMIC_PROJECT_CONFIG_H_SUPPRESS
.
The settings are defined in PlatformIO by build_flags
.
lib_deps =
MCCI LoRaWAN LMIC library
build_flags =
-D ARDUINO_LMIC_PROJECT_CONFIG_H_SUPPRESS
-D CFG_eu868=1
-D CFG_sx1276_radio=1
If your desired transceiver board is not pre-integrated, you need to provide the library with the required information.
You may need to wire up your transceiver. The exact connections are a bit dependent on the transceiver board and Arduino used, so this section tries to explain what each connection is for and in what cases it is (not) required.
Note that the SX127x module runs at 3.3V and likely does not like 5V on its pins (though the datasheet is not say anything about this, and my transceiver did not obviously break after accidentally using 5V I/O for a few hours). To be safe, make sure to use a level shifter, or an Arduino running at 3.3V. The Semtech evaluation board has 100 ohm resistors in series with all data lines that might prevent damage, but I would not count on that.
If you're using a pre-integrated board, you can skip this section.
The SX127x transceivers need a supply voltage between 1.8V and 3.9V.
Using a 3.3V supply is typical. Some modules have a single power pin
(like the HopeRF modules, labeled 3.3V) but others expose multiple power
pins for different parts (like the Semtech evaluation board that has
VDD_RF
, VDD_ANA
and VDD_FEM
), which can all be connected together.
Any GND pins need to be connected to the Arduino GND pin(s).
If you're using a pre-integrated board, you can skip this section.
The primary way of communicating with the transceiver is through SPI (Serial Peripheral Interface). This uses four pins: MOSI, MISO, SCK and SS. The former three need to be directly connected: so MOSI to MOSI, MISO to MISO, SCK to SCK. Where these pins are located on your Arduino varies, see for example the "Connections" section of the Arduino SPI documentation.
The SS (slave select) connection is a bit more flexible. On the SPI slave side (the transceiver), this must be connect to the pin (typically) labeled NSS. On the SPI master (Arduino) side, this pin can connect to any I/O pin. Most Arduinos also have a pin labeled "SS", but this is only relevant when the Arduino works as an SPI slave, which is not the case here. Whatever pin you pick, you need to tell the library what pin you used through the pin mapping (see below).
If you're using a pre-integrated board, you can skip this section.
The DIO (digital I/O) pins on the SX127x can be configured for various functions. The LMIC library uses them to get instant status information from the transceiver. For example, when a LoRa transmission starts, the DIO0 pin is configured as a TxDone output. When the transmission is complete, the DIO0 pin is made high by the transceiver, which can be detected by the LMIC library.
The LMIC library needs only access to DIO0, DIO1 and DIO2, the other
DIOx pins can be left disconnected. On the Arduino side, they can
connect to any I/O pin. If interrupts are used, the accuracy of timing
will be improved, particularly the rest of your loop()
function has
lengthy calculations; but in that case, the enabled DIO pins must all
support rising-edge interrupts. See the Timing section below.
In LoRa mode the DIO pins are used as follows:
- DIO0: TxDone and RxDone
- DIO1: RxTimeout
In FSK mode they are used as follows::
- DIO0: PayloadReady and PacketSent
- DIO2: TimeOut
Both modes need only 2 pins, but the transceiver does not allow mapping them in such a way that all needed interrupts map to the same 2 pins. So, if both LoRa and FSK modes are used, all three pins must be connected.
The pins used on the Arduino side should be configured in the pin
mapping in your sketch, by setting the values of lmic_pinmap::dio[0]
, [1]
, and [2]
(see below).
If you're using a pre-integrated board, you can skip this section.
The transceiver has a reset pin that can be used to explicitly reset it. The LMIC library uses this to ensure the chip is in a consistent state at startup. In practice, this pin can be left disconnected, since the transceiver will already be in a sane state on power-on, but connecting it might prevent problems in some cases.
On the Arduino side, any I/O pin can be used. The pin number used must
be configured in the pin mapping lmic_pinmap::rst
field (see below).
If you're using a pre-integrated board, you can skip this section.
The transceiver contains two separate antenna connections: One for RX and one for TX. A typical transceiver board contains an antenna switch chip, that allows switching a single antenna between these RX and TX connections. Such a antenna switcher can typically be told what position it should be through an input pin, often labeled RXTX.
The easiest way to control the antenna switch is to use the RXTX pin on the SX127x transceiver. This pin is automatically set high during TX and low during RX. For example, the HopeRF boards seem to have this connection in place, so they do not expose any RXTX pins and the pin can be marked as unused in the pin mapping.
Some boards do expose the antenna switcher pin, and sometimes also the SX127x RXTX pin. For example, the SX1272 evaluation board calls the former FEM_CTX and the latter RXTX. Again, simply connecting these together with a jumper wire is the easiest solution.
Alternatively, or if the SX127x RXTX pin is not available, LMIC can be configured to control the antenna switch. Connect the antenna switch control pin (e.g. FEM_CTX on the Semtech evaluation board) to any I/O pin on the Arduino side, and configure the pin used in the pin map (see below).
The configuration entry lmic_pinmap::rxtx
configures the pin to be used for the RXTX control function, in terms of the Arduino wire.h
digital pin number. If set to LMIC_UNUSED_PIN
, then the library assumes that software does not need to control the antenna switch.
If you're using a pre-integrated board, you can skip this section.
If an external switch is used, you also must specify the polarity. Some modules want RXTX to be high for transmit, low for receive; Others want it to be low for transmit, high for receive. The Murata module, for example, requires that RXTX be high for receive, low for transmit.
The configuration entry lmic_pinmap::rxtx_rx_active
should be set to the state to be written to the RXTX pin to make the receiver active. The opposite state is written to make the transmitter active. If lmic_pinmap::rxtx
is LMIC_UNUSED_PIN
, then the value of lmic_pinmap::rxtx_rx_active
is ignored.
If you're using a pre-integrated board, you can skip this section.
Refer to the documentation on your board for the required settings.
Remember, for pre-integrated boards, you don't worry about this.
We have details for the following manually-configured boards here:
If your board is not configured, you need at least to provide your own lmic_pinmap
. As described above, a variety of configurations are possible. To tell the LMIC library how your board is configured, you must declare a variable containing a pin mapping struct in your sketch file. If you call os_init()
to initialize the LMIC, you must name this structure lmic_pins
. If you call os_init_ex()
, you may name the structure what you like, but you pass a pointer as the parameter to os_init_ex()
.
Here's an example of a simple initialization:
lmic_pinmap lmic_pins = {
.nss = 6,
.rxtx = LMIC_UNUSED_PIN,
.rst = 5,
.dio = {2, 3, 4},
// optional: set polarity of rxtx pin.
.rxtx_rx_active = 0,
// optional: set RSSI cal for listen-before-talk
// this value is in dB, and is added to RSSI
// measured prior to decision.
// Must include noise guardband! Ignored in US,
// EU, IN, other markets where LBT is not required.
.rssi_cal = 0,
// optional: override LMIC_SPI_FREQ if non-zero
.spi_freq = 0,
};
The names refer to the pins on the transceiver side, the numbers refer
to the Arduino pin numbers (to use the analog pins, use constants like
A0
). For the DIO pins, the three numbers refer to DIO0, DIO1 and DIO2
respectively. Any pins that are not needed should be specified as
LMIC_UNUSED_PIN
. The NSS and dio0 pins are required. The others can
potentially left out (depending on the environments and requirements,
see the notes above for when a pin can or cannot be left out).
In some boards require much more advanced management. The LMIC has a very flexible framework to support this, but it requires you to do some C++ work.
-
You must define a new class derived from
Arduino_LMIC::HalConfiguration_t
. (We'll call thiscMyHalConfiguration_t
). -
This class may define overrides for several methods (discussed below).
-
You must create an instance of your class, e.g.
cMyHalConfiguration_t myHalConfigInstance;
-
You add another entry in your
lmic_pinmap
,pConfig = &myHalConfigInstance
, to link your pin-map to your object.
The full example looks like this:
class cMyHlaConfiguration_t : public Arduino_LMIC::HalConfiguration_t
{
public:
// ...
// put your method function override declarations here.
// this example uses RFO at 10 dBm or less, PA_BOOST up to 17 dBm,
// or the high-power mode above 17 dBm. In other words, it lets the
// LMIC-determined policy determine what's to be done.
virutal TxPowerPolicy_t getTxPowerPolicy(
TxPowerPolicy_t policy,
int8_t requestedPower,
uint32_t frequency
) override
{
return policy;
}
}
-
ostime_t setModuleActive(bool state)
is called by the LMIC to make the module active or to deactivate it (the value ofstate
is true to activate). The implementation must turn power to the module on and otherwise prepare for it to go to work, and must return the number of OS ticks to wait before starting to use the radio. -
void begin(void)
is called during initialization, and is your code's chance to do any early setup. -
void end(void)
is (to be) called during late shutdown. (Late shutdown is not implemented yet; but we wanted to add the API for consistency.) -
bool queryUsingTcxo(void)
shall returntrue
if the module uses a TCXO;false
otherwise. -
TxPowerPolicy_t getTxPowerPolicy(TxPowerPolicy_t policy, int8_t requestedPower, uint32_t frequency)
allows you to override the LMIC's selection of transmit power. If not provided, the default method forces the LMIC to use PA_BOOST mode. (We chose to do this because we found empirically that the Hope RF module doesn't support RFO, and because legacy LMIC code never used anything except PA_BOOST mode.)
Caution: the LMIC has no way of knowing whether the mode you return makes sense. Use of 20 dBm mode without limiting duty cycle can over-stress your module. The LMIC currently does not have any code to duty-cycle US transmissions at 20 dBm. If properly limiting transmissions to 400 milliseconds, a 1% duty-cycle means at most one message every 40 seconds. This shouldn't be a problem in practice, but buggy upper level software still might do things more rapidly.
This board uses the following pin mapping:
const lmic_pinmap lmic_pins = {
.nss = 10,
.rxtx = LMIC_UNUSED_PIN,
.rst = LMIC_UNUSED_PIN, // hardwired to AtMega RESET
.dio = {4, 5, 7},
};
This library provides several examples.
-
ttn-otaa.ino
shows a basic transmission of a "Hello, world!" message using the LoRaWAN protocol. It contains some frequency settings and encryption keys intended for use with The Things Network, but these also correspond to the default settings of most gateways, so it should work with other networks and gateways as well. The example uses over-the-air activation (OTAA) to first join the network to establish a session and security keys. This was tested with The Things Network, but should also work (perhaps with some changes) for other networks. OTAA is the preferred way to work with production LoRaWAN networks. -
ttn-otaa-feather-us915.ino
is a version ofttn-otaa.ino
that has been configured for use with the Feather M0 LoRa, in the US915 region, with The Things Network. Remember that you may also have to changeconfig.h
from defaults. This sketch also works with the MCCI Catena family of products as well as with the Feather 32u4 LoRa. -
ttn-otaa-halconfig-us915.ino
is a version ofttn-otaa.ino
that uses the LMIC automatic configuration system, in the US915 region, with The Things Network. Remember that you may also have to changeconfig.h
from defaults. This sketch works with all the boards listed above under Pre-Integrated Boards. -
ttn-otaa-feather-us915-dht22.ino
is a further refinement ofttn-otaa-feather-us915.ino
. It measures and transmits temperature and relative humidity using a DHT22 sensor. It's only been tested with Feather M0-family products. -
raw.ino
shows how to access the radio on a somewhat low level, and allows to send raw (non-LoRaWAN) packets between nodes directly. This is useful to verify basic connectivity, and when no gateway is available, but this example also bypasses duty cycle checks, so be careful when changing the settings. -
raw-feather.ino
is a version ofraw.ino
that is completely configured for the Adafruit Feather M0 LoRa, and for a variety of other MCCI products. -
[
raw-halconfig.ino](examples/raw-halconfig/raw-halconfig.ino) is like the other
raw` examples, but is most general. It's configured according to the LMIC's auto-configuration mechanism, and adapts according to the selected region. -
ttn-abp.ino
shows a basic transmission of a "Hello, world!" message using the LoRaWAN protocol. This example uses activation-by-personalization (ABP, preconfiguring a device address and encryption keys), and does not employ over-the-air activation.ABP should not be used if you have access to a production gateway and network; it's not compliant with LoRaWAN standards, it's not FCC compliant, and it's uses spectrum in a way that's unfair to other users. However, it's often the most economical way to get your feet wet with this technology. It's possible to do ABP compliantly with the LMIC framework, but you need to have FRAM storage and a framework that saves uplink and downlink counts across reboots and resets. See, for example, Catena-Arduino-Platform.
-
ttn-abp-feather-us915-dht22.ino
refinesttn-abp.ino
by configuring for use with the Feather M0 LoRa in the US915 region, with a single-channel gateway on The Things Network; it measures and transmits temperature and relative humidity using a DHT22 sensor. It's only been tested with Feather M0-family products.ABP should not be used if you have access to a production gateway and network; it's not compliant with LoRaWAN standards, it's not FCC compliant, and it's uses spectrum in a way that's unfair to other users. However, it's often the most economical way to get your feet wet with this technology. It's possible to do ABP compliantly with the LMIC framework, but you need to have FRAM storage and a framework that saves uplink and downlink counts across reboots and resets. See, for example, Catena-Arduino-Platform.
-
header_test.ino
just tests the header files; it's used for regression testing. -
compliance-otaa-halconfig.ino
is a test sketch that is used for LoRaWAN compliance testing. -
helium-us9115.ino
is a complete example for using the LMIC on the Helium network. It's very similar to the OTAA examples, but sets up the prejoin parameters properly for the initial deployment of Helium LoRaWAN support. -
ttn-otaa-network-time.ino
demonstrates use of the network time request. Network time requests are not supported by The Things Network as of the time of writing.
The library is responsible for keeping track of time of certain network events, and scheduling other events relative to those events. In particular, the library must note when a packet finishes transmitting, so it can open up the RX1 and RX2 receive windows at a fixed time after the end of transmission. The library does this by watching for rising edges on the DIO0 output of the SX127x, and noting the time.
The library observes and processes rising edges on the pins as part of os_runloop()
processing.
This can be configured in one of two ways (see
Controlling use of interrupts).
By default, the routine hal_io_check()
polls the enabled pins to determine whether an event has occurred. This approach
allows use of any CPU pin to sense the DIOs, and makes no assumptions about
interrupts. However, it means that the end-of-transmit event is not observed
(and time-stamped) until os_runloop()
is called.
Optionally, you can configure the LMIC library to use interrupts. The
interrupt handlers capture the time of
the event. Actual processing is done the next time that os_runloop()
is called, using the captured time. However, this requires that the
DIO pins be wired to Arduino pins that support rising-edge interrupts.
Fortunately, LoRa is a fairly slow protocol and the timing of the receive windows is not super critical. To synchronize transmitter and receiver, a preamble is first transmitted. Using LoRaWAN, this preamble consists of 8 symbols, of which the receiver needs to see 4 symbols to lock on. The current implementation tries to enable the receiver for 6 symbol times slightly before the start of the receive window.
The HAL bases all timing on the Arduino micros()
timer, which has a platform-specific
granularity and accuracy, and is based on the primary microcontroller clock.
If using an internal oscillator that is less than 100ppm accurate but better than 4000 ppm accurate, or if your other loop()
processing
is time consuming, you can use LMIC_setClockError()
to cause the library to leave the radio on longer. Note that for various reasons, it is not practical to set enormous clock errors. Oscillators that are 4000 ppm accurate or worse should be supplemented or disciplined with a better timing source. The LoRaWAN spec, for class B, implicitly assumes 100 ppm accuracy in the clock.
Users of older versions of the library were advised to set large clock errors if they were experiencing timing problems. However, close analysis and debugging during the preparation of v3.1.0 of this library revealed that the real errors were in the timing calculations in the library. Once those were corrected, the need for large clock error settings was reduced. It's still possible to use large clock errors if needed, but this must be enabled via a compile time switch.
An even more accurate solution could be to use a dedicated timer with an
input capture unit, that can store the timestamp of a change on the DIO0
pin (the only one that is timing-critical) entirely in hardware.
Experience shows that this is not normally required, so we leave this as
a customization to be performed on a platform-by-platform basis. We provide
a special API, radio_irq_handler_v2(u1_t dio, ostime_t tEvent)
. This
API allows you to supply a hardware-captured time for extra accuracy.
The practical consequence of inaccurate timing is reduced battery life; the LMIC must turn on the receiver earlier in order to be sure to capture downlink packets. However, this is a second order effect on class A devices; every receive is preceded by a transmit, which takes approximately ten times as much power per millisecond as a receive.
You may call this routine during initialization to inform the LMIC code about the timing accuracy of your system.
enum { MAX_CLOCK_ERROR = 65535 };
void LMIC_setClockError(
u2_t error
);
This function sets the anticipated relative clock error. MAX_CLOCK_ERROR
represents +/- 100%, and 0 represents no additional clock compensation.
To allow for an error of 20%, you would call
LMIC_setClockError(MAX_CLOCK_ERROR * 20 / 100);
Setting a high clock error causes the RX windows to be opened earlier than it otherwise would be. This causes more power to be consumed. For Class A devices, this extra power is not substantial, but for Class B devices, this can be significant.
For a variety of reasons, the LMIC normally ignores clock errors greater than 4000 ppm (0.4%). The compile-time flag LMIC_ENABLE_arbitrary_clock_error
can remove this limit. To do this, define it to a non-zero value.
This clock error is not reset by LMIC_reset()
.
Note that the data rate used for downlink packets in the RX2 window varies by region. Consult your network's manual for any divergences from the LoRaWAN Regional Parameters. This library assumes that the network follows the regional default.
Some networks use different values than the specification. For example, in Europe, the specification default is DR0 (SF12, 125 kHz bandwidth). However, iot.semtech.com and The Things Network both used SF9 / 125 kHz or DR3). If using over-the-air activation (OTAA), the network will download RX2 parameters as part of the JoinAccept message; the LMIC will honor the downloaded parameters.
However, when using personalized activate (ABP), it is your
responsibility to set the right settings, e.g. by adding this to your
sketch (after calling LMIC_setSession
). ttn-abp.ino
already does
this.
LMIC.dn2Dr = DR_SF9;
It is generally important to make LoRaWAN messages as small as practical. Extra bytes mean extra transmit time, which wastes battery power and interferes with other nodes on the network.
To simplify coding, the Arduino header file <lmic.h> defines some data encoding utility functions to encode floating-point data into uint16_t
values using sflt16
or uflt16
bit layout. For even more efficiency, there are versions that use only the bottom 12 bits of the uint16_t
, allowing for other bits to be carried in the top 4 bits, or for two values to be crammed into three bytes.
uint16_t LMIC_f2sflt16(float)
converts a floating point number to asflt16
-encodeduint16_t
.uint16_t LMIC_f2uflt16(float)
converts a floating-point number to auflt16
-encodeduint16_t
.uint16_t LMIC_f2sflt12(float)
converts a floating-point number to asflt12
-encodeduint16_t
, leaving the top four bits of the result set to zero.uint16_t LMIC_f2uflt12(float)
converts a floating-point number to auflt12
-encodeduint16_t
, leaving the top four bits of the result set to zero.
JavaScript code for decoding the data can be found in the following sections.
A sflt16
datum represents an unsigned floating point number in the range [0, 1.0), transmitted as a 16-bit field. The encoded field is interpreted as follows:
bits | description |
---|---|
15 | Sign bit |
14..11 | binary exponent b |
10..0 | fraction f |
The corresponding floating point value is computed by computing f
/2048 * 2^(b
-15). Note that this format is deliberately not IEEE-compliant; it's intended to be easy to decode by hand and not overwhelmingly sophisticated. However, it is similar to IEEE format in that it uses sign-magnitude rather than twos-complement for negative values.
For example, if the data value is 0x8D, 0x55, the equivalent floating point number is found as follows.
- The full 16-bit number is 0x8D55.
- Bit 15 is 1, so this is a negative value.
b
is 1, andb
-15 is -14. 2^-14 is 1/16384f
is 0x555. 0x555/2048 = 1365/2048 is 0.667f * 2^(b-15)
is therefore 0.667/16384 or 0.00004068- Since the number is negative, the value is -0.00004068
Floating point mavens will immediately recognize:
- This format uses sign/magnitude representation for negative numbers.
- Numbers do not need to be normalized (although in practice they always are).
- The format is somewhat wasteful, because it explicitly transmits the most-significant bit of the fraction. (Most binary floating-point formats assume that
f
is is normalized, which means by definition that the exponentb
is adjusted andf
is shifted left until the most-significant bit off
is one. Most formats then choose to delete the most-significant bit from the encoding. If we were to do that, we would insist that the actual value off
be in the range 2048..4095, and then transmit onlyf - 2048
, saving a bit. However, this complicates the handling of gradual underflow; see next point.) - Gradual underflow at the bottom of the range is automatic and simple with this encoding; the more sophisticated schemes need extra logic (and extra testing) in order to provide the same feature.
function sflt162f(rawSflt16)
{
// rawSflt16 is the 2-byte number decoded from wherever;
// it's in range 0..0xFFFF
// bit 15 is the sign bit
// bits 14..11 are the exponent
// bits 10..0 are the the mantissa. Unlike IEEE format,
// the msb is explicit; this means that numbers
// might not be normalized, but makes coding for
// underflow easier.
// As with IEEE format, negative zero is possible, so
// we special-case that in hopes that JavaScript will
// also cooperate.
//
// The result is a number in the open interval (-1.0, 1.0);
//
// throw away high bits for repeatability.
rawSflt16 &= 0xFFFF;
// special case minus zero:
if (rawSflt16 == 0x8000)
return -0.0;
// extract the sign.
var sSign = ((rawSflt16 & 0x8000) != 0) ? -1 : 1;
// extract the exponent
var exp1 = (rawSflt16 >> 11) & 0xF;
// extract the "mantissa" (the fractional part)
var mant1 = (rawSflt16 & 0x7FF) / 2048.0;
// convert back to a floating point number. We hope
// that Math.pow(2, k) is handled efficiently by
// the JS interpreter! If this is time critical code,
// you can replace by a suitable shift and divide.
var f_unscaled = sSign * mant1 * Math.pow(2, exp1 - 15);
return f_unscaled;
}
A uflt16
datum represents an unsigned floating point number in the range [0, 1.0), transmitted as a 16-bit field. The encoded field is interpreted as follows:
bits | description |
---|---|
15..12 | binary exponent b |
11..0 | fraction f |
The corresponding floating point value is computed by computing f
/4096 * 2^(b
-15). Note that this format is deliberately not IEEE-compliant; it's intended to be easy to decode by hand and not overwhelmingly sophisticated.
For example, if the transmitted message contains 0xEB, 0xF7, and the transmitted byte order is big endian, the equivalent floating point number is found as follows.
- The full 16-bit number is 0xEBF7.
b
is therefore 0xE, andb
-15 is -1. 2^-1 is 1/2f
is 0xBF7. 0xBF7/4096 is 3063/4096 == 0.74780...f * 2^(b-15)
is therefore 0.74780/2 or 0.37390
Floating point mavens will immediately recognize:
- There is no sign bit; all numbers are positive.
- Numbers do not need to be normalized (although in practice they always are).
- The format is somewhat wasteful, because it explicitly transmits the most-significant bit of the fraction. (Most binary floating-point formats assume that
f
is is normalized, which means by definition that the exponentb
is adjusted andf
is shifted left until the most-significant bit off
is one. Most formats then choose to delete the most-significant bit from the encoding. If we were to do that, we would insist that the actual value off
be in the range 4096..8191, and then transmit onlyf - 4096
, saving a bit. However, this complicated the handling of gradual underflow; see next point.) - Gradual underflow at the bottom of the range is automatic and simple with this encoding; the more sophisticated schemes need extra logic (and extra testing) in order to provide the same feature.
function uflt162f(rawUflt16)
{
// rawUflt16 is the 2-byte number decoded from wherever;
// it's in range 0..0xFFFF
// bits 15..12 are the exponent
// bits 11..0 are the the mantissa. Unlike IEEE format,
// the msb is explicit; this means that numbers
// might not be normalized, but makes coding for
// underflow easier.
// As with IEEE format, negative zero is possible, so
// we special-case that in hopes that JavaScript will
// also cooperate.
//
// The result is a number in the half-open interval [0, 1.0);
//
// throw away high bits for repeatability.
rawUflt16 &= 0xFFFF;
// extract the exponent
var exp1 = (rawUflt16 >> 12) & 0xF;
// extract the "mantissa" (the fractional part)
var mant1 = (rawUflt16 & 0xFFF) / 4096.0;
// convert back to a floating point number. We hope
// that Math.pow(2, k) is handled efficiently by
// the JS interpreter! If this is time critical code,
// you can replace by a suitable shift and divide.
var f_unscaled = mant1 * Math.pow(2, exp1 - 15);
return f_unscaled;
}
A sflt12
datum represents an signed floating point number in the range [0, 1.0), transmitted as a 12-bit field. The encoded field is interpreted as follows:
bits | description |
---|---|
11 | sign bit |
11..8 | binary exponent b |
7..0 | fraction f |
The corresponding floating point value is computed by computing f
/128 * 2^(b
-15). Note that this format is deliberately not IEEE-compliant; it's intended to be easy to decode by hand and not overwhelmingly sophisticated.
For example, if the transmitted message contains 0x8, 0xD5, the equivalent floating point number is found as follows.
- The full 16-bit number is 0x8D5.
- The number is negative.
b
is 0x1, andb
-15 is -14. 2^-14 is 1/16384f
is 0x55. 0x55/128 is 85/128, or 0.66f * 2^(b-15)
is therefore 0.66/16384 or 0.000041 (to two significant digits)- The decoded number is therefore -0.000041.
Floating point mavens will immediately recognize:
- This format uses sign/magnitude representation for negative numbers.
- Numbers do not need to be normalized (although in practice they always are).
- The format is somewhat wasteful, because it explicitly transmits the most-significant bit of the fraction. (Most binary floating-point formats assume that
f
is is normalized, which means by definition that the exponentb
is adjusted andf
is shifted left until the most-significant bit off
is one. Most formats then choose to delete the most-significant bit from the encoding. If we were to do that, we would insist that the actual value off
be in the range 128 .. 256, and then transmit onlyf - 128
, saving a bit. However, this complicates the handling of gradual underflow; see next point.) - Gradual underflow at the bottom of the range is automatic and simple with this encoding; the more sophisticated schemes need extra logic (and extra testing) in order to provide the same feature.
- It can be strongly argued that dropping the sign bit would be worth the effort, as this would get us 14% more resolution for a minor amount of work.
function sflt12f(rawSflt12)
{
// rawSflt12 is the 2-byte number decoded from wherever;
// it's in range 0..0xFFF (12 bits). For safety, we mask
// on entry and discard the high-order bits.
// bit 11 is the sign bit
// bits 10..7 are the exponent
// bits 6..0 are the the mantissa. Unlike IEEE format,
// the msb is explicit; this means that numbers
// might not be normalized, but makes coding for
// underflow easier.
// As with IEEE format, negative zero is possible, so
// we special-case that in hopes that JavaScript will
// also cooperate.
//
// The result is a number in the open interval (-1.0, 1.0);
//
// throw away high bits for repeatability.
rawSflt12 &= 0xFFF;
// special case minus zero:
if (rawSflt12 == 0x800)
return -0.0;
// extract the sign.
var sSign = ((rawSflt12 & 0x800) != 0) ? -1 : 1;
// extract the exponent
var exp1 = (rawSflt12 >> 7) & 0xF;
// extract the "mantissa" (the fractional part)
var mant1 = (rawSflt12 & 0x7F) / 128.0;
// convert back to a floating point number. We hope
// that Math.pow(2, k) is handled efficiently by
// the JS interpreter! If this is time critical code,
// you can replace by a suitable shift and divide.
var f_unscaled = sSign * mant1 * Math.pow(2, exp1 - 15);
return f_unscaled;
}
A uflt12
datum represents an unsigned floating point number in the range [0, 1.0), transmitted as a 16-bit field. The encoded field is interpreted as follows:
bits | description |
---|---|
11..8 | binary exponent b |
7..0 | fraction f |
The corresponding floating point value is computed by computing f
/256 * 2^(b
-15). Note that this format is deliberately not IEEE-compliant; it's intended to be easy to decode by hand and not overwhelmingly sophisticated.
For example, if the transmitted message contains 0x1, 0xAB, the equivalent floating point number is found as follows.
- The full 16-bit number is 0x1AB.
b
is therefore 0x1, andb
-15 is -14. 2^-14 is 1/16384f
is 0xAB. 0xAB/256 is 0.67f * 2^(b-15)
is therefore 0.67/16384 or 0.0000408 (to three significant digits)
Floating point mavens will immediately recognize:
- There is no sign bit; all numbers are positive.
- Numbers do not need to be normalized (although in practice they always are).
- The format is somewhat wasteful, because it explicitly transmits the most-significant bit of the fraction. (Most binary floating-point formats assume that
f
is is normalized, which means by definition that the exponentb
is adjusted andf
is shifted left until the most-significant bit off
is one. Most formats then choose to delete the most-significant bit from the encoding. If we were to do that, we would insist that the actual value off
be in the range 256 .. 512, and then transmit onlyf - 256
, saving a bit. However, this complicates the handling of gradual underflow; see next point.) - Gradual underflow at the bottom of the range is automatic and simple with this encoding; the more sophisticated schemes need extra logic (and extra testing) in order to provide the same feature.
function uflt12f(rawUflt12)
{
// rawUflt12 is the 2-byte number decoded from wherever;
// it's in range 0..0xFFF (12 bits). For safety, we mask
// on entry and discard the high-order bits.
// bits 11..8 are the exponent
// bits 7..0 are the the mantissa. Unlike IEEE format,
// the msb is explicit; this means that numbers
// might not be normalized, but makes coding for
// underflow easier.
// As with IEEE format, negative zero is possible, so
// we special-case that in hopes that JavaScript will
// also cooperate.
//
// The result is a number in the half-open interval [0, 1.0);
//
// throw away high bits for repeatability.
rawUflt12 &= 0xFFF;
// extract the exponent
var exp1 = (rawUflt12 >> 8) & 0xF;
// extract the "mantissa" (the fractional part)
var mant1 = (rawUflt12 & 0xFF) / 256.0;
// convert back to a floating point number. We hope
// that Math.pow(2, k) is handled efficiently by
// the JS interpreter! If this is time critical code,
// you can replace by a suitable shift and divide.
var f_unscaled = sSign * mant1 * Math.pow(2, exp1 - 15);
return f_unscaled;
}
-
HEAD has the following changes:
-
#537 fixes a compile error in SX1272 support. (Thanks @ricaun.) Version is v3.1.0.10.
-
v3.1.0 officially adopts the changes from v3.0.99. There were dozens of changes; check the GitHub issue logs and change logs. This was a breaking release (due to changes in data layout in the LMIC structure; the structure is accessed by apps).
-
v3.0.99 (the pre-release for v3.1.0) added the following changes. (This is not an exhaustive list.) Note that the behavior of the LMIC changes in important ways, as it now enforces the LoRaWAN mandated maximum frame size for a given data rate. For Class A devices, this may cause your device to go silent after join, if you're not able to handle the frame size dictated by the parameters downloaded to the device by the network during join. The library will attempt to find a data rate that will work, but there is no guarantee that the network has provided such a data rate.
- #470 corrects the name of AU915 region. #516 makes sure that
LMIC_REGION_au921
is defined (but deprecated) for backward compatibility. - #452 fixes a bug #450 in
LMIC_clrTxData()
that would cause join hiccups if called while (1) a join was in progress and (2) a regular data packet was waiting to be uplinked after the join completes. Also fixes AS923- and AU915-specific bugs #446, #447, #448. Version isv3.0.99.5
. - #443 addresses a number of problems found in cooperation with RedwoodComm. They suggested a timing improvement to speed testing; this lead to the discovery of a number of problems. Some were in the compliance framework, but one corrects timing for very high spreading factors, several (#442, #436, #435, #434 fix glaring problems in FSK support; #249 greatly enhances stability by making API calls much less likely to crash the LMIC if it's active. Version is v3.0.99.3.
- #388, #389, #390 change the LMIC to honor the maximum frame size for a given DR in the current region. This proves to be a breaking change for many applications, especially in the US, because DR0 in the US supports only an 11-byte payload, and many apps were ignoring this. Additional error codes were defined so that apps can detect and recover from this situation, but they must detect; otherwise they run the risk of being blocked from the network by the LMIC. Because of this change, the next version of the LMIC will be V3.1 or higher, and the LMIC version for development is bumped to 3.0.99.0.
- #401 adds 865 MHz through 868 MHz to the "1%" band for EU.
- #395 corrects pin-mode initialization if using
hal_interrupt_init()
. - #385 corrects an error handling data rate selection for
TxParamSetupReq
, found in US-915 certification testing. (v2.3.2.71) - #378 completely reworks MAC downlink handling. Resulting code passes the LoRaWAN V1.5 EU certification test. (v2.3.2.70)
- #360 adds support for the KR-920 regional plan.
- #470 corrects the name of AU915 region. #516 makes sure that
-
v2.3.2 is a patch release. It incorporates two pull requests.
-
v2.3.1 is a patch release. It adds
<arduino_lmic_user_configuration.h>
, which loads the pre-processor LMIC configuration variables into scope (issue #199). -
v2.3.0 introduces two important changes.
-
The pin-map is extended with an additional field
pConfig
, pointing to a C++ class instance. This instance, if provided, has extra methods for dealing with TCXO control and other fine details of operating the radio. It also gives a natural way for us to extend the behavior of the HAL. -
Pinmaps can be pre-configured into the library, so that users don't have to do this in every sketch.
Accompanying this was a fairly large refactoring of inner header files. We now have top-level header file
<arduino_lmic_hal_configuration.h>
, which provides much the same info as the original<hal/hal.h>
, without bringing most of the LMIC internal definitions into scope. We also changed the SPI API based on a suggestion from@manuelbl
, making the HAL more friendly to structured BSPs (and also making the SPI API potentially faster). -
-
Interim bug fixes: added a new API (
radio_irq_handler_v2()
), which allows the caller to provide the timestamp of the interrupt. This allows for more accurate timing, because the knowledge of interrupt overhead can be moved to a platform-specific layer (#148). Fixed compile issues on ESP32 (#140 and #153). We added ESP32 and 32u4 as targets in CI testing. We switched CI testing to Arduino IDE 1.8.7. Fixed issue #161 selecting the Japan version of as923 usingCFG_as923jp
(selecting viaCFG_as923
andLMIC_COUNTRY_CODE=LMIC_COUNTRY_CODE_JP
worked). Fixed #38 -- now any call to hal_init() will put the NSS line in the idle (high/inactive) state. As a side effect, RXTX is initialized, and RESET code changed to set value before transitioning state. Likely no net effect, but certainly more correct. -
V2.2.2 adds
ttn-abp-feather-us915-dht22.ino
example, and fixes some documentation typos. It also fixes encoding of theMargin
field of theDevStatusAns
MAC message (#130). This makes Arduino LMIC work with networks implemented with LoraServer. -
V2.2.1 corrects the value of
ARDUINO_LMIC_VERSION
(#123), allows ttn-otaa-feather-us915 example to compile for the Feather 32u4 LoRa (#116), and addresses documentation issues (#122, #120). -
V2.2.0 adds encoding functions and
tn-otaa-feather-us915-dht22.ino
example. Plus a large number of issues: #59, #60, #63, #64 (listen-before-talk for Japan), #65, #68, #75, #78, #80, #91, #98, #101. Added full Travis CI testing, switched to travis-ci.com as the CI service. Prepared to publish library in the official Arduino library list. -
V2.1.5 fixes issue #56 (a documentation bug). Documentation was quickly reviewed and other issues were corrected. The OTAA examples were also updated slightly.
-
V2.1.4 fixes issues #47 and #50 in the radio driver for the SX1276 (both related to handling of output power control bits).
-
V2.1.3 has a fix for issue #43: handling of
LinkAdrRequest
was incorrect for US915 and AU915; when TTN added ADR support on US and AU, the deficiency was revealed (and caused an ASSERT). -
V2.1.2 has a fix for issue #39 (adding a prototype for
LMIC_DEBUG_PRINTF
if needed). Fully upward compatible, so just a patch. -
V2.1.1 has the same content as V2.1.2, but was accidentally released without updating
library.properties
. -
V2.1.0 adds support for the Murata LoRaWAN module.
-
V2.0.2 adds support for additional regions.
This library started from the IBM V1.5 open-source code.
-
Thomas Telkamp and Matthijs Kooijman ported V1.5 to Arduino and did a lot of bug fixing.
-
Terry Moore, LeRoy Leslie, Frank Rose, and ChaeHee Won did a lot of work on US support.
-
Terry Moore added the AU915, AS923, KR920 and IN866 regions, and created the regionalization framework, and did corrections for LoRaWAN 1.0.3 compliance testing.
-
@tanupoo
of the WIDE Project debugged AS923JP and LBT support. -
@frazar
contributed numerous features, e.g. network time support, CI testing, documentation improvements. -
@manuelbl
contributed numerous ESP32-related patches and improvements. -
@ngraziano
did extensive testing and contributed numerous ADR-related patches.
There are many others, who have contributed code and also participated in discussions, performed testing, reported problems and results. Thanks to all who have participated.
LoRa is a registered trademark of Semtech Corporation. LoRaWAN is a registered trademark of the LoRa Alliance.
MCCI and MCCI Catena are registered trademarks of MCCI Corporation.
All other trademarks are the properties of their respective owners.
The upstream files from IBM v1.6 are based on the Berkeley license, and the merge which synchronized this repository therefore migrated the core files to the Berkeley license. However, modifications made in the Arduino branch were done under the Eclipse license, so the overall license of this repository is still Eclipse Public License v1.0. The examples which use a more liberal license. Some of the AES code is available under the LGPL. Refer to each individual source file for more details, but bear in mind that until the upstream developers look into this issue, it is safest to assume the Eclipse license applies.
MCCI invests time and resources providing this open source code, please support MCCI and open-source hardware by purchasing products from MCCI, Adafruit and other open-source hardware/software vendors!
For information about MCCI's products, please visit store.mcci.com.