MultiTech / Mbed OS Dot-Examples

Example programs for MultiTech Dot devices demonstrating how to use the Dot devices and the Dot libraries for LoRa communication.

Dependencies:   ISL29011

Dependents:   Dot-Examples-delujoc

This project has moved to github

Please see GitHub Dot-Examples

Dot Library Not Included!

Because these example programs can be used for both mDot and xDot devices, the LoRa stack is not included. The libmDot library should be imported if building for mDot devices. The libxDot library should be imported if building for xDot devices.

Dot Library Limitations

Commit messages in Dot Library repositories specify the version of the library and the version of mbed-os it was compiled against. We recommend building your application with the version of mbed-os specified in the commit message of the version of the Dot library you're using. This will ensure that you don't run into any runtime issues caused by differences in the mbed-os versions.

Example Programs Description

This application contains multiple example programs. Each example demonstrates a different way to configure and use a Dot. A short summary of each example is provided below. Common code used by multiple examples is in the dot_utils.cpp file.

All examples print logging, including RX data, on the USB debug port at 115200 baud. Each example defaults the Dot's configuration and saves the new configuration to NVM.

OTA Example

This example demonstrates configuring the Dot for OTA join mode and entering sleep or deepsleep mode between transactions with the gateway. If deepsleep mode is used, the session is saved and restored so that a rejoin is not necessary after waking up even though RAM contents have been lost. ACKs are disabled, but network link checks are configured - if enough link checks are missed, the Dot will no longer be considered joined to the network and will attempt to rejoin before transmitting more data.

AUTO_OTA Example

This example demonstrates configuring the Dot for AUTO_OTA join mode and entering sleep or deepsleep mode between transactions with the gateway. AUTO_OTA join mode automatically saves and restores the session when deepsleep mode is used, so the manual saving and restoring of the session is not necessary. ACKs are disabled, but network link checks are configured - if enough link checks are missed, the Dot will no longer be considered joined to the network and will attempt to rejoin before transmitting more data.

Manual Example

This example demonstrates configuring the Dot for MANUAL join mode and entering sleep or deepsleep mode between transactions with the gateway. The Dot must be provisioned on the gateway before its packets will be accepted! Follow these steps to provision the Dot on a Conduit gateway:

  • ssh into the conduit
  • use the lorq-query application to provision the Dot on the gateway
    • lora-query -a 01020304 A 0102030401020304 <your Dot's device ID> 01020304010203040102030401020304 01020304010203040102030401020304
    • if any of the credentials change on the Dot side, they must be updated on the gateway side as well

To provision a Dot on a third-party gateway, see the gateway or network provider documentation.

Class B Example

This example demonstrates how to configure the dot for an OTA join, how to acquire a lock on a GPS synchronized beacon, and then to subsequently enter class B mode of operation. After a successful join, the device will request to the dot-library to switch to class B. When this happens, the library will send an uplink to the network server (hence we must be joined first before entering this mode) requesting the GPS time to calculate when the next beacon is expected. Once this time elapses, the dot will open an rx window to demodulate the broadcasted beacon and fire an mDotEvent::BeaconRx event upon successful reception. After the beacon is received, the example sends an uplink which will have the class B bit in the packet's frame control set to indicate to the network server that downlinks may now be scheduled on ping slots. The lora-query application can be used to configure a Conduit gateway to communicate with a Dot in class B mode. For information on how to inform a third-party gateway that a Dot is operating in class B mode, see the gateway or network provider documentation.

Class C Example

This example demonstrates configuring the Dot for OTA join mode and communicating with the gateway using class C mode. In class C mode the gateway can send a packet to the Dot at any time, so it must be listening whenever it is not transmitting. This means that the Dot cannot enter sleep or deepsleep mode. The gateway will not immediately send packets to the Dot (outside the receive windows following a transmission from the Dot) until it is informed that the Dot is operating in class C mode. The lora-query application can be used to configure a Conduit gateway to communicate with a Dot in class C mode. For information on how to inform a third-party gateway that a Dot is operating in class C mode, see the gateway or network provider documentation.

FOTA Example

Full FOTA support is available on mDot and on xDot with external flash. See this article for details on adding external flash for xDot FOTA.

Without external flash xDot can use the FOTA example to dynamically join a multicast session only. After joining the multicast session the received Fragmentation packets could be handed to a host MCU for processing and at completion the firmware can be loaded into the xDot using the bootloader and y-modem. See xDot Developer Guide.

This example demonstrates how to incorporate over-the-air updates to an application. The example uses a Class C application. Class A or B functionality could also be used. The device will automatically enter into Class C operation for the FOTA operation, Class B would be disabled during the FOTA transfer.

  • Add the following code to allow Fota to use the Dot instance

examples/src/fota_example.cpp

    // Initialize FOTA singleton
    Fota::getInstance(dot);
  • Add fragmentation and multicast handling the the PacketRx event

examples/inc/RadioEvent.h

    virtual void PacketRx(uint8_t port, uint8_t *payload, uint16_t size, int16_t rssi, int8_t snr, lora::DownlinkControl ctrl, uint8_t slot, uint8_t retries, uint32_t address, uint32_t fcnt, bool dupRx) {
        mDotEvent::PacketRx(port, payload, size, rssi, snr, ctrl, slot, retries, address, fcnt, dupRx);

#if ACTIVE_EXAMPLE == FOTA_EXAMPLE
        if(port == 200 || port == 201 || port == 202) {
            Fota::getInstance()->processCmd(payload, port, size);
        }
#endif
    }

A definition is needed to enable FOTA.

mbed_app.json

{
    "macros": [
        "FOTA=1"
    ]
}


Peer to Peer Example

This example demonstrates configuring Dots for peer to peer communication without a gateway. It should be compiled and run on two Dots. Peer to peer communication uses LoRa modulation but uses a single higher throughput (usually 500kHz or 250kHz) datarate. It is similar to class C operation - when a Dot isn't transmitting, it's listening for packets from the other Dot. Both Dots must be configured exactly the same for peer to peer communication to be successful.

Choosing An Example Program and Channel Plan

Only the active example is compiled. The active example can be updated by changing the ACTIVE_EXAMPLE definition in the examples/example_config.h file.

By default the OTA_EXAMPLE will be compiled and the US915 channel plan will be used.

example_config.h

#ifndef __EXAMPLE__CONFIG_H__
#define __EXAMPLE__CONFIG_H__

#define OTA_EXAMPLE              1  // see ota_example.cpp
#define AUTO_OTA_EXAMPLE         2  // see auto_ota_example.cpp
#define MANUAL_EXAMPLE           3  // see manual_example.cpp
#define PEER_TO_PEER_EXAMPLE     4  // see peer_to_peer_example.cpp
#define CLASS_C_EXAMPLE          5  // see class_c_example.cpp

// the active example is the one that will be compiled
#if !defined(ACTIVE_EXAMPLE)
#define ACTIVE_EXAMPLE  OTA_EXAMPLE
#endif

// the active channel plan is the one that will be compiled
// options are :
//      CP_US915
//      CP_AU915
//      CP_EU868
//      CP_KR920
//      CP_AS923
//      CP_AS923_JAPAN
#if !defined(CHANNEL_PLAN)
#define CHANNEL_PLAN CP_US915
#endif

#endif


Compile the AUTO_OTA_EXAMPLE and use the EU868 channel plan instead.

example_config.h

#ifndef __EXAMPLE__CONFIG_H__
#define __EXAMPLE__CONFIG_H__

#define OTA_EXAMPLE              1  // see ota_example.cpp
#define AUTO_OTA_EXAMPLE         2  // see auto_ota_example.cpp
#define MANUAL_EXAMPLE           3  // see manual_example.cpp
#define PEER_TO_PEER_EXAMPLE     4  // see peer_to_peer_example.cpp
#define CLASS_C_EXAMPLE          5  // see class_c_example.cpp

// the active example is the one that will be compiled
#if !defined(ACTIVE_EXAMPLE)
#define ACTIVE_EXAMPLE  AUTO_OTA_EXAMPLE
#endif

// the active channel plan is the one that will be compiled
// options are :
//      CP_US915
//      CP_AU915
//      CP_EU868
//      CP_KR920
//      CP_AS923
//      CP_AS923_JAPAN
#if !defined(CHANNEL_PLAN)
#define CHANNEL_PLAN CP_EU868
#endif

#endif


Dot Libraries

Stable and development libraries are available for both mDot and xDot platforms. The library chosen must match the target platform. Compiling for the mDot platform with the xDot library or vice versa will not succeed.

mDot Library

Development library for mDot.

libmDot-dev

Stable library for mDot.

libmDot-stable


For mbed-os 5 use:

Import librarylibmDot-mbed5

Stable version of the mDot library for mbed 5. This version of the library is suitable for deployment scenarios. See lastest commit message for version of mbed-os library that has been tested against.

Last commit 25 Mar 2020 by MultiTech

xDot Library

Development library for xDot.

libxDot-dev

Stable library for xDot.

libxDot-stable


For mbed-os 5 use:

Import librarylibxDot-mbed5

Stable version of the xDot library for mbed 5. This version of the library is suitable for deployment scenarios.

Last commit 02 Apr 2020 by MultiTech

examples/src/auto_ota_example.cpp@9:72d3203279b2, 2016-10-07 (annotated)

Committer:
Mike Fiore
Date:
Fri Oct 07 15:48:23 2016 -0500
Revision:
9:72d3203279b2
Parent:
5:97ed5f2f099e
Child:
12:ec9768677cea
save configuration after updating

Who changed what in which revision?

UserRevisionLine numberNew contents of line
mfiore 0:a151a6350d7f 1 #include "dot_util.h"
mfiore 0:a151a6350d7f 2
mfiore 0:a151a6350d7f 3 #if ACTIVE_EXAMPLE == AUTO_OTA_EXAMPLE
mfiore 0:a151a6350d7f 4
Mike Fiore 5:97ed5f2f099e 5 /////////////////////////////////////////////////////////////
Mike Fiore 5:97ed5f2f099e 6 // * these options must match the settings on your gateway //
Mike Fiore 5:97ed5f2f099e 7 // * edit their values to match your configuration //
Mike Fiore 5:97ed5f2f099e 8 // * frequency sub band is only relevant for the 915 bands //
Mike Fiore 5:97ed5f2f099e 9 // * either the network name and passphrase can be used or //
Mike Fiore 5:97ed5f2f099e 10 // the network ID (8 bytes) and KEY (16 bytes) //
Mike Fiore 5:97ed5f2f099e 11 /////////////////////////////////////////////////////////////
mfiore 3:0e3e776e2862 12 static std::string network_name = "MultiTech";
mfiore 3:0e3e776e2862 13 static std::string network_passphrase = "MultiTech";
Mike Fiore 5:97ed5f2f099e 14 static uint8_t network_id[] = { 0x6C, 0x4E, 0xEF, 0x66, 0xF4, 0x79, 0x86, 0xA6 };
Mike Fiore 5:97ed5f2f099e 15 static uint8_t network_key[] = { 0x1F, 0x33, 0xA1, 0x70, 0xA5, 0xF1, 0xFD, 0xA0, 0xAB, 0x69, 0x7A, 0xAE, 0x2B, 0x95, 0x91, 0x6B };
mfiore 3:0e3e776e2862 16 static uint8_t frequency_sub_band = 0;
mfiore 0:a151a6350d7f 17 static bool public_network = false;
mfiore 0:a151a6350d7f 18 static uint8_t ack = 1;
mfiore 0:a151a6350d7f 19
mfiore 0:a151a6350d7f 20 // deepsleep consumes slightly less current than sleep
mfiore 0:a151a6350d7f 21 // in sleep mode, IO state is maintained, RAM is retained, and application will resume after waking up
mfiore 0:a151a6350d7f 22 // in deepsleep mode, IOs float, RAM is lost, and application will start from beginning after waking up
mfiore 0:a151a6350d7f 23 // if deep_sleep == true, device will enter deepsleep mode
mfiore 1:c4915e00d2ce 24 static bool deep_sleep = true;
mfiore 0:a151a6350d7f 25
mfiore 0:a151a6350d7f 26 mDot* dot = NULL;
mfiore 0:a151a6350d7f 27
mfiore 0:a151a6350d7f 28 Serial pc(USBTX, USBRX);
mfiore 0:a151a6350d7f 29
mfiore 0:a151a6350d7f 30 #if defined(TARGET_XDOT_L151CC)
mfiore 0:a151a6350d7f 31 I2C i2c(I2C_SDA, I2C_SCL);
mfiore 0:a151a6350d7f 32 ISL29011 lux(i2c);
mfiore 0:a151a6350d7f 33 #else
mfiore 0:a151a6350d7f 34 AnalogIn lux(XBEE_AD0);
mfiore 0:a151a6350d7f 35 #endif
mfiore 0:a151a6350d7f 36
mfiore 0:a151a6350d7f 37 int main() {
mfiore 0:a151a6350d7f 38 pc.baud(115200);
mfiore 0:a151a6350d7f 39
mfiore 0:a151a6350d7f 40 mts::MTSLog::setLogLevel(mts::MTSLog::TRACE_LEVEL);
mfiore 0:a151a6350d7f 41
mfiore 0:a151a6350d7f 42 dot = mDot::getInstance();
mfiore 0:a151a6350d7f 43
mfiore 0:a151a6350d7f 44 // make sure library logging is turned on
mfiore 0:a151a6350d7f 45 dot->setLogLevel(mts::MTSLog::INFO_LEVEL);
mfiore 0:a151a6350d7f 46
mfiore 2:ffac7b141b72 47 // update configuration if necessary
mfiore 0:a151a6350d7f 48 // in AUTO_OTA mode the session is automatically saved, so saveNetworkSession and restoreNetworkSession are not needed
mfiore 0:a151a6350d7f 49 if (dot->getJoinMode() != mDot::AUTO_OTA) {
mfiore 0:a151a6350d7f 50 logInfo("changing network join mode to AUTO_OTA");
mfiore 0:a151a6350d7f 51 if (dot->setJoinMode(mDot::AUTO_OTA) != mDot::MDOT_OK) {
mfiore 0:a151a6350d7f 52 logError("failed to set network join mode to AUTO_OTA");
mfiore 0:a151a6350d7f 53 }
mfiore 0:a151a6350d7f 54 }
Mike Fiore 5:97ed5f2f099e 55 // in OTA and AUTO_OTA join modes, the credentials can be passed to the library as a name and passphrase or an EUI and KEY
Mike Fiore 5:97ed5f2f099e 56 // only one method or the other should be used!
Mike Fiore 5:97ed5f2f099e 57 // network ID = crc64(network name)
Mike Fiore 5:97ed5f2f099e 58 // network KEY = cmac(network passphrase)
Mike Fiore 5:97ed5f2f099e 59 update_ota_config_name_phrase(network_name, network_passphrase, frequency_sub_band, public_network, ack);
Mike Fiore 9:72d3203279b2 60 //update_ota_config_id_key(network_id, network_key, frequency_sub_band, public_network, ack);
mfiore 2:ffac7b141b72 61
mfiore 2:ffac7b141b72 62 // save changes to configuration
mfiore 2:ffac7b141b72 63 logInfo("saving configuration");
mfiore 2:ffac7b141b72 64 if (!dot->saveConfig()) {
mfiore 2:ffac7b141b72 65 logError("failed to save configuration");
mfiore 2:ffac7b141b72 66 }
mfiore 2:ffac7b141b72 67
mfiore 2:ffac7b141b72 68 // display configuration
mfiore 0:a151a6350d7f 69 display_config();
mfiore 0:a151a6350d7f 70
mfiore 0:a151a6350d7f 71 while (true) {
mfiore 0:a151a6350d7f 72 uint16_t light;
mfiore 0:a151a6350d7f 73 std::vector<uint8_t> tx_data;
mfiore 0:a151a6350d7f 74
mfiore 0:a151a6350d7f 75 // join network if not joined
mfiore 0:a151a6350d7f 76 if (!dot->getNetworkJoinStatus()) {
mfiore 0:a151a6350d7f 77 join_network();
mfiore 0:a151a6350d7f 78 }
mfiore 0:a151a6350d7f 79
mfiore 0:a151a6350d7f 80 #if defined(TARGET_XDOT_L151CC)
mfiore 0:a151a6350d7f 81 // configure the ISL29011 sensor on the xDot-DK for continuous ambient light sampling, 16 bit conversion, and maximum range
mfiore 0:a151a6350d7f 82 lux.setMode(ISL29011::ALS_CONT);
mfiore 0:a151a6350d7f 83 lux.setResolution(ISL29011::ADC_16BIT);
mfiore 0:a151a6350d7f 84 lux.setRange(ISL29011::RNG_64000);
mfiore 0:a151a6350d7f 85
mfiore 0:a151a6350d7f 86 // get the latest light sample and send it to the gateway
mfiore 0:a151a6350d7f 87 light = lux.getData();
mfiore 0:a151a6350d7f 88 tx_data.push_back((light >> 8) & 0xFF);
mfiore 0:a151a6350d7f 89 tx_data.push_back(light & 0xFF);
mfiore 0:a151a6350d7f 90 logInfo("light: %lu [0x%04X]", light, light);
mfiore 0:a151a6350d7f 91 send_data(tx_data);
mfiore 0:a151a6350d7f 92
mfiore 0:a151a6350d7f 93 // put the LSL29011 ambient light sensor into a low power state
mfiore 0:a151a6350d7f 94 lux.setMode(ISL29011::PWR_DOWN);
mfiore 0:a151a6350d7f 95 #else
mfiore 0:a151a6350d7f 96 // get some dummy data and send it to the gateway
mfiore 0:a151a6350d7f 97 light = lux.read_u16();
mfiore 0:a151a6350d7f 98 tx_data.push_back((light >> 8) & 0xFF);
mfiore 0:a151a6350d7f 99 tx_data.push_back(light & 0xFF);
mfiore 0:a151a6350d7f 100 logInfo("light: %lu [0x%04X]", light, light);
mfiore 0:a151a6350d7f 101 send_data(tx_data);
mfiore 0:a151a6350d7f 102 #endif
mfiore 0:a151a6350d7f 103
mfiore 0:a151a6350d7f 104 // ONLY ONE of the three functions below should be uncommented depending on the desired wakeup method
mfiore 0:a151a6350d7f 105 //sleep_wake_rtc_only(deep_sleep);
mfiore 0:a151a6350d7f 106 //sleep_wake_interrupt_only(deep_sleep);
mfiore 0:a151a6350d7f 107 sleep_wake_rtc_or_interrupt(deep_sleep);
mfiore 0:a151a6350d7f 108 }
mfiore 0:a151a6350d7f 109
mfiore 0:a151a6350d7f 110 return 0;
mfiore 0:a151a6350d7f 111 }
mfiore 0:a151a6350d7f 112
mfiore 0:a151a6350d7f 113 #endif