Create Application using SX1272 + X-NUCLEO-IKS01A2

Dependencies:   X_NUCLEO_IKS01A2 driver_mbed_TH02 mbed LoRaWAN-lib-v1_0_1 SX1272Lib

Fork of LoRaWAN-SX1272-Application-Demo by Semtech

LoRaWAN-NAMote72 Application Demo is a Class-A device example project using LoRaWAN-lib and SX1272Lib libraries.

Comissioning.h (LoRaWAN Network Configuration)

The end-device can be activated in one of the two ways:

Over the Air (OTA) activation can be enabled as shown in the figure below. /media/uploads/ubhat/ota_enable.png

The end-device must be configured with the following parameters:

  • LORAWAN_DEVICE_EUI (8 Bytes) : Fist 3 Bytes is the Organizationally Unique Identifier (OUI) followed by 5 bytes of unique ID. If not defined by user, then the firmware automatically assigns one to the end-device
  • LORAWAN_APPLICATION_EUI (8 Bytes)
  • LORAWAN_APPLICATION_KEY (or DEVKEY) (16 Bytes)

/media/uploads/ubhat/ota_eui.png

Activation by Personalization (ABP) can be enabled as shown in the figure below. /media/uploads/ubhat/abp_enable.png

The end-device must be configured with the following parameters:

  • LORAWAN_DEVICE_ADDRESS (4 Bytes) : If not defined by user, then the firmware automatically assigns one to the end-device
  • LORAWAN_NWKSKEY (16 Bytes)
  • LORAWAN_APPSKEY (16 Bytes)

/media/uploads/ubhat/abp_key.png

Config.h (LoRaWAN Communication Parameters)

  • Mode of Operation : Hybrid If the end-device needs to be configured to operate over 8-channels, then Hybrid Mode needs to be enabled /media/uploads/ubhat/hybridenable.png
  • Mode of Operation : Frequency Hop If the end-device needs to be configured to operate over 64-channels, then Hybrid Mode needs to be disabled
  • Delay between successive JOIN REQUESTs : The delay between successive Join Requests (until the end-device joins the network) can be configured using the parameter OVER_THE_AIR_ACTIVATION_DUTYCYCLE
  • Inter-Frame Delay : One can change the delay between each frame transmission using APP_TX_DUTYCYCLE It is advisable that APP_TX_DUTYCYCLE is greater than or equal to 3sec.
  • Data Rate : The data rate can be configured as per LoRaWAN specification using the paramter LORAWAN_DEFAULT_DATARATE. The range of values are DR_0, DR_1, DR_2, DR_3 and DR_4
  • Confirmed/Unconfirmed Messages : The uplink message or payload can be chosen to be confirmed or unconfirmed using the parameter LORAWAN_CONFIRMED_MSG_ON. When set to 1, the transmitted messages need to be confirmed with an ACK by the network server in the subsequent RX window. When set to 0, no ACK is requested.
  • ADR ON/OFF : The ADR can be enabled or disabled using the parameter LORAWAN_ADR_ON. When set to 1, ADR is enabled and disabled when set to 0.
  • Application Port : The application port can be set using parameter LORAWAN_APP_PORT.
  • Payload Length : The lenght of the payload (in bytes) to be transmitted can be configured using LORAWAN_APP_DATA_SIZE
  • Transmit Power : The transmit power can be configured using LORAWAN_TX_POWER (LoRaMAC verifies if the set power is compliant with the LoRaWAN spec and FCC guidelines)

/media/uploads/ubhat/loraconfig.png

Main.cpp (Device State Machine)

The end-device state machine is defined.

  • Initial State : Device is initialized.
  • Join State : For OTA, Join Request is transmitted to the network until Join Accept is received by the end-device. Join event function is called that sets Red LED ON.
  • Send State : Transmit payload frame is prepared. Tx event is called that blinks the Red LED indicating uplink transmission.
  • Cycle State : Next packet transmission is scheduled

LoRaEventProc.cpp (Events and On-board Application)

Define events during Join, Tx & Rx. Prepare TX packet by appending with appropriate application data.

/media/uploads/ubhat/lora_events.png

  • PrepareLoRaFrame(uint8_t port ) : Prepare LoRa payload frame with on-board application data such as GPS, Temperature, Battery, etc. LoRa.ApplicationCall(AppType ) calls application AppType defined in LoRaApp.cpp. AppType is defined in LoRaApp.h

/media/uploads/ubhat/lora_app.png

LoRaApp.cpp

User-defined applications such as GPS, Temp, Accelerometer, LED indications etc. Event based actions such as LED blink on Tx, LED toggle on downlink etc /media/uploads/ubhat/apptype.png

LoRaDeviceStateProc.cpp

Process function calls corresponding to different Device states /media/uploads/ubhat/device_state.png

LoRaMacLayerService.cpp

Define MAC Layer Services: MLME & MCPS

system/crypto/aes.h

Committer:
ubhat
Date:
2018-08-19
Revision:
11:2707638f5915
Parent:
0:6cc76d70e2a1

File content as of revision 11:2707638f5915:

/*
 ---------------------------------------------------------------------------
 Copyright (c) 1998-2008, Brian Gladman, Worcester, UK. All rights reserved.

 LICENSE TERMS

 The redistribution and use of this software (with or without changes)
 is allowed without the payment of fees or royalties provided that:

  1. source code distributions include the above copyright notice, this
     list of conditions and the following disclaimer;

  2. binary distributions include the above copyright notice, this list
     of conditions and the following disclaimer in their documentation;

  3. the name of the copyright holder is not used to endorse products
     built using this software without specific written permission.

 DISCLAIMER

 This software is provided 'as is' with no explicit or implied warranties
 in respect of its properties, including, but not limited to, correctness
 and/or fitness for purpose.
 ---------------------------------------------------------------------------
 Issue 09/09/2006

 This is an AES implementation that uses only 8-bit byte operations on the
 cipher state.
 */

#ifndef AES_H
#define AES_H

#if 1
#  define AES_ENC_PREKEYED  /* AES encryption with a precomputed key schedule  */
#endif
#if 0
#  define AES_DEC_PREKEYED  /* AES decryption with a precomputed key schedule  */
#endif
#if 0
#  define AES_ENC_128_OTFK  /* AES encryption with 'on the fly' 128 bit keying */
#endif
#if 0
#  define AES_DEC_128_OTFK  /* AES decryption with 'on the fly' 128 bit keying */
#endif
#if 0
#  define AES_ENC_256_OTFK  /* AES encryption with 'on the fly' 256 bit keying */
#endif
#if 0
#  define AES_DEC_256_OTFK  /* AES decryption with 'on the fly' 256 bit keying */
#endif

#define N_ROW                   4
#define N_COL                   4
#define N_BLOCK   (N_ROW * N_COL)
#define N_MAX_ROUNDS           14

typedef uint8_t return_type;

/*  Warning: The key length for 256 bit keys overflows a byte
    (see comment below)
*/

typedef uint8_t length_type;

typedef struct
{   uint8_t ksch[(N_MAX_ROUNDS + 1) * N_BLOCK];
    uint8_t rnd;
} aes_context;

/*  The following calls are for a precomputed key schedule

    NOTE: If the length_type used for the key length is an
    unsigned 8-bit character, a key length of 256 bits must
    be entered as a length in bytes (valid inputs are hence
    128, 192, 16, 24 and 32).
*/

#if defined( AES_ENC_PREKEYED ) || defined( AES_DEC_PREKEYED )

return_type aes_set_key( const uint8_t key[],
                         length_type keylen,
                         aes_context ctx[1] );
#endif

#if defined( AES_ENC_PREKEYED )

return_type aes_encrypt( const uint8_t in[N_BLOCK],
                         uint8_t out[N_BLOCK],
                         const aes_context ctx[1] );

return_type aes_cbc_encrypt( const uint8_t *in,
                         uint8_t *out,
                         int32_t n_block,
                         uint8_t iv[N_BLOCK],
                         const aes_context ctx[1] );
#endif

#if defined( AES_DEC_PREKEYED )

return_type aes_decrypt( const uint8_t in[N_BLOCK],
                         uint8_t out[N_BLOCK],
                         const aes_context ctx[1] );

return_type aes_cbc_decrypt( const uint8_t *in,
                         uint8_t *out,
                         int32_t n_block,
                         uint8_t iv[N_BLOCK],
                         const aes_context ctx[1] );
#endif

/*  The following calls are for 'on the fly' keying.  In this case the
    encryption and decryption keys are different.

    The encryption subroutines take a key in an array of bytes in
    key[L] where L is 16, 24 or 32 bytes for key lengths of 128,
    192, and 256 bits respectively.  They then encrypts the input
    data, in[] with this key and put the reult in the output array
    out[].  In addition, the second key array, o_key[L], is used
    to output the key that is needed by the decryption subroutine
    to reverse the encryption operation.  The two key arrays can
    be the same array but in this case the original key will be
    overwritten.

    In the same way, the decryption subroutines output keys that
    can be used to reverse their effect when used for encryption.

    Only 128 and 256 bit keys are supported in these 'on the fly'
    modes.
*/

#if defined( AES_ENC_128_OTFK )
void aes_encrypt_128( const uint8_t in[N_BLOCK],
                      uint8_t out[N_BLOCK],
                      const uint8_t key[N_BLOCK],
                      uint8_t o_key[N_BLOCK] );
#endif

#if defined( AES_DEC_128_OTFK )
void aes_decrypt_128( const uint8_t in[N_BLOCK],
                      uint8_t out[N_BLOCK],
                      const uint8_t key[N_BLOCK],
                      uint8_t o_key[N_BLOCK] );
#endif

#if defined( AES_ENC_256_OTFK )
void aes_encrypt_256( const uint8_t in[N_BLOCK],
                      uint8_t out[N_BLOCK],
                      const uint8_t key[2 * N_BLOCK],
                      uint8_t o_key[2 * N_BLOCK] );
#endif

#if defined( AES_DEC_256_OTFK )
void aes_decrypt_256( const uint8_t in[N_BLOCK],
                      uint8_t out[N_BLOCK],
                      const uint8_t key[2 * N_BLOCK],
                      uint8_t o_key[2 * N_BLOCK] );
#endif

#endif