wayne roberts
end node on synchronous star LoRa network.
Dependencies: SX127x sx12xx_hal TSL2561
radio chip selection
Radio chip driver is not included, allowing choice of radio device.
If you're using SX1272 or SX1276, then import sx127x driver into your program.
if you're using SX1261 or SX1262, then import sx126x driver into your program.
if you're using SX1280, then import sx1280 driver into your program.
If you're using NAmote72 or Murata discovery, then you must import only sx127x driver.
This project for use with LoRaWAN_singlechannel_gateway project.
Alternately gateway running on raspberry pi can be used as gateway.
LoRaWAN on single radio channel
Network description is at gateway project page. Synchronous star network.
Hardware Support
This project supports SX1276 and SX1272, sx126x kit, sx126x shield, and sx128x 2.4GHz. The ST board B-L072Z-LRWAN1 is also supported (TypeABZ module). When B-L072Z-LRWAN1 target is selected, TARGET_DISCO_L072CZ_LRWAN1 is defined by tools, allowing correct radio driver configuration for this platform. Alternately, any mbed board that can use LoRa radio shield board should work, but NUCLEO boards are tested.
End-node Unique ID
DevEUI is created from CPU serial number. AppEUI and AppKey are declared as software constants.
End-node Configuration
Data rate definition LORAMAC_DEFAULT_DATARATE configured in LoRaMac-definitions.h. See gateway project page for configuration of gateway.
LoRaWAN addressing is configured in Comissioning.h; only OTA mode is functional.
Header file board/lora_config.h, selects application layer options (i.e. sensors) to be compiled in.
Serial Interface
Serial port operates at 115200bps.
Application layer single_us915_main.cpp User button triggers uplink (i.e. blue button on nucleo board), or jumper enables continuously sends repeated uplink packets. The MAC layer holds each uplink request until the allocated timeslot.
| command | arguments | description |
|---|---|---|
? | - | print available commands |
. (period) | - | print status (DevEUI, DevAddr, etc) |
ul | length integer | set payload length of test uplink packets |
sensor demo
Selected grove sensors may be plugged into SX1272 shield.
To enable, edit lora_config.h to define SENSORS.
Sensor connections on SX1272MB2xAS:
| D8 D9: button | RX TX: (unused) | A3 A4: Rotary Angle Sensor |
| D6 D7: RGB LED | SCL SDA: digital light sensor | A1 A2: Rotary Angle Sensor |
Digital input pin, state reported via uplink: PC8
Digital output pin, controlled via downlink: PC6
PWM out: PB_10
Jumper enables auto-repeated transmit: PC10 and PC12 on NUCLEO board, located on end of morpho headers nearby JP4.
Diff: system/crypto/gladman_aes.h
- Revision:
- 0:8f0d0ae0a077
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/system/crypto/gladman_aes.h Thu May 18 15:11:53 2017 -0700
@@ -0,0 +1,160 @@
+/*
+ ---------------------------------------------------------------------------
+ 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