STMICROELECTRONICS STM32L0 Ultra Low Power MCUs User Manual

Contents hide

1 STMICROELECTRONICS STM32L0 Ultra Low Power MCUs

2 Product Information

3 Product Usage Instructions

4 General information

5 Overview

6 AT commands

7 Examples

8 Documents / Resources

8.1 References

9 Related Posts

STMICROELECTRONICS STM32L0 Ultra Low Power MCUs

Product Information

The RYLR993 module is a LoRa SOC core-based device that uses the AT command set developed by REYAX for controlling the module. The module supports LoRaWAN communication and provides features such as activation by personalization, over-the-air activation, and long-range radio technology. The module also supports the use of keys, IDs, and EUIs for management purposes. Additionally, the module can be used to join and send data on the LoRa network and perform radio tests.

Product Usage Instructions

To use the RYLR993 module, the user must send AT commands to the module using a serial interface. The AT command set provided by REYAX consists of a series of short text strings that can be used to perform various operations such as joining the LoRa network, sending data to the network, and setting parameters. The user can also manage keys, IDs, and EUIs using the module.
For example, to join the LoRa network, the user can send the following command:

AT+JOIN
- To check the link status, the user can send:

AT+LINKC
- To send data to the LoRa network, the user can use the following command:

AT+SEND
- The RYLR993 module also supports radio test commands. To perform a radio test, the user can use the following command:

AT+RADIO=1
- For more detailed information on using the RYLR993 module, please refer to the product user manual.

General information

The document applies to the REYAX RYLR993 module that are LoRa SOC core-based devices.

Acronym	Definition
ABP	Activation by personalization
ETSI	European telecommunications standards institute
LoRa	Long range radio technology
LoRaWAN	LoRa wide-area network
OTAA	Over-the-air activation
RF	Radio frequency
RSSI	Received signal strength indicator
SNR	Signal-to-noise ratio

Overview

The following sections contain the interface description, the AT commands definition, and the description of some use cases and of the embedded software.

AT commands

The AT command set is a standard developed by REYAX to control module. The command set consists of a series of short text strings for performing operations such as joining, data exchange and parameters setting.
The AT commands are used to drive the LoRa module and to send data. The AT commands are sent through the UART.

Baud rate: 9600

Data: 8 bits
Parity: none

Stop: 1 bit
Flow control: none

All commands are of the form AT+XXX, with XXX denoting the command. The following command behaviors are available:

AT+XXX? provides a short help of the given command (such as AT+DEUI?).

AT+XXX is used to run a command (such as AT+JOIN).
AT+XXX=? is used to get the value of a given command (such as AT+CFS=?).

AT+XXX=<value> is used to provide a value to a command (such as AT+SEND=2:Hello).

Output of the commands is provided on the UART. The output format is typically:

Considering:

<value><CR><LF> is returned when help AT+XXX? and get AT+XXX=? commands are run.

<CR> and <LF> stands for the carriage return and line feed.
When no value is returned, then <value><CR><LF> is not returned at all.

Every command, except ATZ (MCU reset), returns a status string, that is preceded and followed by <CR><LF>. Possible status are:
- OK: command run correctly without error.
- AT_ERROR: generic error
- AT_PARAM_ERROR: parameter of the command is wrong.
- AT_BUSY_ERROR: LoRa network is busy, so the command could not complete.
- AT_TEST_PARAM_OVERFLOW: parameter is too long.
- AT_NO_NETWORK_JOINED: LoRa network is not joined.
- AT_RX_ERROR: error detection during the reception of the command

More details on each command description and examples are given in the next sections. Each command preceded by # is provided by the host to the module, then the return of the module is printed.

AT_RX_ERROR

In case of AT_RX_ERROR, the command is corrupted when received in AT_Slave. Hence the command is not run.
However, in case of long commands, some spurious characters can still be in the queue, ready to be processed as a command. So, in case the user receives an AT_RX_ERROR, the user must first send <CR><LF> to purge the queue, and then send back the same command so that it is processed.

Example

AT command overview

Command	Parameters	Description
General Commands
AT	None	Check if the interface is available.
AT	[?]	Help of all supported commands.
ATZ	None	Reset
AT+VL	[=verb_lvl], where verb_lvl = [0:3]	Sets/gets the verbose level.
AT+LTIME	[=?]	Gets the local time in UTC format.
Keys, IDs and EUIs management commands
AT+APPEUI	[=01:02:03:04:05:06:07:08]	Sets/gets the application EUI.
AT+NWKKEY	[=2B:7E:15:16:28:AE:D2:A6:AB:F 7:15:88:09:CF:4F:3C]	Sets/gets the network root key
AT+APPKEY	[=2B:7E:15:16:28:AE:D2:A6:AB:F 7:15:88:09:CF:4F:3C]	Sets/gets the application root key.

Command	Parameters	Description
AT+APPSKEY	[=2B:7E:15:16:28:AE:D2:A6:AB:F 7:15:88:09:CF:4F:3C]	Sets/gets the application session key.
AT+NWKSKEY	[=2B:7E:15:16:28:AE:D2:A6:AB:F 7:15:88:09:CF:4F:3C]	Sets/gets the network session key.
AT+DADDR	[=01:02:0A:0B]	Sets/gets the device address.
AT+DEUI	[=01:23:45:67:89:AB:CD:EF]	Sets/gets the module unique ID.
AT+NWKID	[=127]	Sets/gets the network ID.
LoRa join and send data commands
AT+JOIN	[=mode] where mode = 0 (ABP) or mode = 1 (OTAA)	Joins the network.
AT+LINKC	–	Piggyback link check MAC command request to the next uplink
AT+SEND	[=port_nb:confirmedmode:data] where confirmedmode = 0 or 1.	Sends packets to the network.
LoRa network management commands
AT+VER	[=?]	Gets the LoRaWAN version.
AT+ADR	[=adr_enable] where adr_enable = 0 or 1	Sets/gets the adaptive data rate functionality.
AT+DR	[=datarate] where datarate = [0:7]	Sets/gets the data rate.
AT+BAND	[=region] where region = [0:9]	Sets/gets the active region
AT+CLASS	[=class] where class = [A, B or C]	Sets/gets the LoRa class.
AT+DCS	[=dutycycle] where dutycycle = 0 or 1	Sets/gets duty cycle settings.
AT+JN1DL	[=delay] where delay in ms	Sets/gets the join delay on Rx window 1.
AT+JN2DL		Sets/gets the join delay on Rx window 2.
AT+RX1DL		Sets/gets the delay of the Rx window 1.
AT+RX2DL		Sets/gets the delay of the Rx window 2.
AT+RX2DR	[=datarate] where X = [0:7]	Sets/gets data rate of the Rx window 2.
AT+RX2FQ	[=freq] where freq in Hz	Sets/gets the frequency of the Rx window 2.
AT+TXP	[=txpow] where txpow = [0:7]	Sets/gets the transmit power.
AT+PGSLOT	[=periodicity]	Sets/gets the ping slot.
Radio tests commands
AT+TTONE	None	Sets the RF tone test.
AT+TRSSI	None	Sets the RF RSSI tone test.
AT+TCONF	[=freq:pow:bw:sf:cr:lna:pa :mod:paylen:freqdev :lowdropt:BT] [=868000000:14:125:12:4/5:0:0: 1:255:0:0:0 for example	Sets/gets the config LoRa RF test.
AT+TTX	[=nb_packets_sent]	Sets the number of packets to be sent for PER RF Tx test.
AT+TRX	[=nb_packets_received]	Sets the number of packets to be received for PER RF Rx test.

Command	Parameters	Description
AT+CERTIF	[=mode] where mode = 0 (ABP) or mode = 1 (OTAA)	Sets the module in LoRaWAN certification with join mode.
AT+TTH	[=<Fstart>, <Fstop>, <FDelta>,<PacketNb>]	Starts RF Tx hopping test from Fstart to Fstop (in Hz or MHz), Fdelta in Hz
AT+TOFF	None	Stops RF tests.
Information command
AT+BAT	None	Gets the battery level.

Event table
The table below details the events that the AT_Slave application sends as a notification to the host module.

Event	Return value	Description
+EVT:JOINED	None	Notifies an host module has been join on the gateway by OTAA.
+EVT:JOIN FAILED	None	Notifies the host module has not completed the join transaction (ID/Keys error, Tx not received by the gateway, Rx not received or not decrypted). In this case, the AT+JOIN must be recalled.
+EVT:	:<port>:<size>:<payload>	Notifies the host module that an asynchronous frame has been received on a RX window with downlink frame.
+EVT:	RX_<slot>:<DR>:<RSSI>:<SNR>	Notifies the host module that an asynchronous frame has been received on a RX window with downlink parameters.
+EVT:	RX_<slot>:<DR>:<RSSI>:<SNR> :<DMODM>:<GWN>	Notifies the host module that an asynchronous frame has been received on a RX window with extended downlink parameters. This event replaces the previous event when at least one link check request (AT+LINKC) has been executed.
+EVT:SEND_CONFIRMED	None	Notifies the host module that a Tx frame has been acknowledge by the gateway.

General commands

Description	Attention is used to check if the link is working properly.
Syntax	AT<CR>
Arguments	None
Response	None
Result code	<CR><LF>OK<CR><LF>

Example:

AT?

Description	Provides the short help of all supported commands.
Syntax	AT?<CR>
Arguments	None
Response	None
Result code	<CR><LF>OK<CR><LF>

Example:

ATZ – MCU reset

Description	The command generates a NVIC reset: resets the whole system including radio and microprocessor.
Syntax	ATZ<CR>
Arguments	None
Response	None
Result code	None (NVIC_Reset action)

Example:

The displayed keys by command above after ###### (DevEUI, AppEui, and DevAddr) are just informative and not a command response.

AT+VL – Verbose level

Description	Sets/gets the verbose level of the application.
Syntax	AT+VL=<verbose_leve><CR> AT+VL=?<CR>
Arguments	<verbose_level>, the default is 1 (VLEVEL_L) 0: VLEVEL_OFF 1: VLEVEL_L 2: VLEVEL_M 3: VLEVEL_H
Response	<verbose_level><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+LTIME – Local time in UTC format

Description	Gets the local time in UTC format.
Syntax	AT+LTIME=?<CR>
Arguments	None
Response	<local time><CR><LF>
Result code	<CR><LF>OK<CR><LF>

Example:

AT+OPMODE – Set operating mode

Description	Select LoRaWAN mode or REYAX RYLR998 proprietary mode
Syntax	AT+OPMODE=<mode><CR> AT+OPMODE=?<CR>
Arguments	<mode>, the default is 0 (LoRaWAN mode) 0: LoRaWAN mode 1: REYAX RYLR998 proprietary mode *RYLR993 can’t set up the NETWORKID, only accept the default NETWORKID=18 of the RYLR998. When entry this mode please refer to the AT command of RYLR998.
Response	<mode><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Example:

Keys, IDs and EUIs management

AT+APPEUI – Application identifier

Description	Sets/gets the application EUI.
Syntax	AT+APPEUI=<id><CR> AT+APPEUI=?<CR>
Arguments	<id>, 8-byte value separated by ”:” (hexadecimal format string)
Response	<id><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+NWKKEY – Network root key

Description	Sets/gets the network root key. This key is used only in OTAA mode.
Syntax	AT+NWKKEY=<key><CR> AT+NWKKEY=?<CR>
Arguments	<id>, 4-byte value separated by ”:” (hexadecimal format string)
Response	<key><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+APPKEY – Application root key

Description	Sets/gets the application root key. This key is used only in OTAA mode.
Syntax	AT+APPKEY=<key><CR> AT+APPKEY=?<CR>
Arguments	<key>, 16-byte value separated by ”:” (hexadecimal format string)
Response	<key><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+APPSKEY – Application session key

Description	Sets/gets the application session key. This key is used only in OTAA and APB modes. In OTAA mode, this key is replaced during the derivation process with the application root key and JoinAccept response information.
Syntax	AT+APPSKEY=<key><CR> AT+APPSKEY=?<CR>
Arguments	<key>, 16-byte value separated by ”:” (hexadecimal format string)
Response	<key><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Example:

AT+NWKSKEY – Network session key

Description	Sets/gets the network session key. This key is used in OTAA and ABP modes. In OTAA mode, this key is replaced during the derivation process with the network’s root key and JoinAccept response information.
Syntax	AT+NWKSKEY=<key><CR> AT+NWKSEY=?<CR>
Arguments	<key>, 16-byte value separated by ”:” (hexadecimal format string)
Response	<key><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Example:

AT+DADDR – Device address

Description	Sets/gets the device address.
Syntax	AT+DADDR=<address><CR> AT+DADDR=?<CR>
Arguments	<address>, 4-byte value separated by ”:” (hexadecimal format string)
Response	<address><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+DEUI – Device EUI

Description	Sets/gets the device EUI.
Syntax	AT+DEUI=<EUI><CR> AT+DEUI=?<CR>
Arguments	<EUI>, 8-byte value separated by ”:” (hexadecimal format string)
Response	<EUI><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+NWKID – Network ID

Description	Sets/gets the network ID.
Syntax	AT+NWKID=<id><CR> AT+NWKID=?<CR>
Arguments	<id>, 1-byte decimal value from 0 to 127
Response	<id><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

Join and send data on LoRa network

Description	Join the LoRa network.
Syntax	AT+JOIN=<mode><CR>
Arguments	<mode> 0: join to a network by ABP 1: join to a network by OTAA
Response	+EVT:JOINED or +EVT:JOIN_FAILED
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

AT+JOIN – Join LoRa network

Examples:

AT+LINKC – Link check request

Description	Piggyback link check MAC command request to the next uplink. The DemodMargin and NbGateways output information is provided into the extended Rx events +EVT:RX.
Syntax	AT+LINKC<CR>
Arguments	None
Response	None
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+SEND – Send data to LoRa network

Description	Sends application packets with specified and AppPort and payload to LoRaWAN network.
Syntax	AT+SEND=<port>:<ack>:<payload><CR>
Arguments	• <port>: application port to be transmitted • <ack> – 0: unconfirmed message – 1: confirmed message • <payload>: payload in hexadecimal format strings (maximum length is 242 bytes)
Response	+EVT:SEND_CONFIRMED
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF> <CR><LF>AT_DUTYCYLE_RESTRICTED<CR><LF> <CR><LF>AT_NO_NET_JOINED<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF> <CR><LF>AT_CRYPTO_ERROR<CR><LF> <CR><LF>AT_ERROR<CR><LF>

Examples:

LoRa network management

AT+VER – Firmware version

Description	Gets the version of the AT_Slave firmware.
Syntax	APP_VERSION: Vx.y.z<CR><LF> MW_LORAWAN_VERSION: Va.b.c<CR><LF> MW_RADION_VERSION: Vd.e.f<CR><LF>
Arguments	None
Response	<version><CR><LF>
Result code	<CR><LF>OK<CR><LF>

Example:

AT+ADR – Adaptive data rate functionality

Description	Sets/gets the adaptive data rate functionality.
Syntax	AT+ADR=<enabled><CR> AT+ADR=?<CR>
Arguments	<enabled> • 0: ADR disabled • 1: ADR enabled (default)
Response	<enabled><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+DR – Data rate

Description	Sets/gets the Tx data rate.
Syntax	AT+DR=<data rate><CR> AT+DR=?<CR>
Arguments	<data rate> in the range [0,1,2,3,4,5,6,7]
Response	<data rate><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Note: To be able to set data rate, the ADR must be disabled.

Examples:

AT+BAND – Active region

Description	Sets/gets the active region.
Syntax	AT+BAND=<band><CR> AT+BAND=?<CR>
Arguments	<band>: number corresponding to active regions 0: AS923 (RYLR993) 1: AU915 (RYLR993_AK) 5: EU868 6: KR920 (RYLR993_AK) 7: IN865 (RYLR993) 8: US915<default> 9: RU864 (RYLR993_AK)
Response	<band><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+CLASS – LoRa class

Description	Sets/gets the LoRa class.
Syntax	AT+CLASS=<class><CR> AT+CLASS=?<CR>
Arguments	<class>: must be A, B or C.
Response	<class><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_ERROR<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF> <CR><LF>AT_NO_CLASS_B_ENABLE<CR><LF> <CR><LF>AT_NO_NET_JOINED<CR><LF>

Examples:

AT+DCS – Duty cycle settings

Description	Sets/gets the duty cycle settings.
Syntax	AT+DCS=<dutyCycleEnable><CR> AT+DCS=?<CR>
Arguments	<dutyCycleEnable> 0: duty cycle disabled 1: duty cycle enabled
Response	<dutyCycleEnable><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+JN1DL – Join delay on Rx window 1

Description	Sets/gets the join accept delay between the end of the Tx and the join Rx window 1 (in ms).
Syntax	AT+JN1DL=<delay><CR> AT+JN1DL=?<CR>
Arguments	<delay>: value in ms
Response	<delay><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+JN2DL – Join delay on Rx window 2

Description	Sets/gets the join accept delay between the end of the Tx and the join Rx window 2 (in ms).
Syntax	AT+JN2DL=<delay><CR> AT+JN2DL=?<CR>
Arguments	<delay>: value in ms
Response	<delay><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+RX1DL – Delay of the Rx window 1

Description	Sets/gets the delay between the end of the Tx and the Rx window 1 (in ms).
Syntax	AT+RX1DL=<delay><CR> AT+RX1DL=?<CR>
Arguments	<delay>: value in ms
Response	<delay><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+RX2DL – Delay of the Rx window 2

Description	Sets/gets the delay between the end of the Tx and the Rx window 2 (in ms).
Syntax	AT+RX2DL=<delay><CR> AT+RX2DL=?<CR>
Arguments	<delay>: value in ms
Response	<delay><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+RX2DR – Data rate of the Rx window 2

Description	Sets/gets the Rx window 2 data rate (0-7 corresponding to DR_X).
Syntax	AT+RX2DR=<datarate><CR> AT+RX2DR=?<CR>
Arguments	<datarate>: value in range [0:15]
Response	<datarate><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+RX2FQ – Frequency of the Rx window 2

Description	Sets/gets the Rx window 2 frequency.
Syntax	AT+RX2FQ=<freq><CR> AT+RX2FQ=?<CR>
Arguments	<freq>: value in Hz
Response	<freq><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+TXP – Transmit power

Description	Sets/gets the transmit power.
Syntax	AT+TXP=<TxPow><CR> AT+TXP=?<CR>
Arguments	<TxPow>: must be in the range of the region activated in the range [0:15].
Response	<TxPow><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+PGSLOT – Ping slot

Description	Sets/gets the unicast ping slot periodicity.
Syntax	AT+PGSLOT=<periodicity><CR> AT+PGSLOT=?<CR>
Arguments	<periodicity>: periodicity to be transmitted, must be in the range [0:7] Ping slot periodicity is 2< periodicity >, in seconds.
Response	<periodicity><CR><LF>
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Example

Radio test commands

AT+TTONE – RF tone test

Description	Starts a RF tone test.
Syntax	AT+TTONE<CR>
Arguments	None
Response	None
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF>

Example:

AT+TRSSI – RF RSSI tone test

Description	Starts a RF RSSI tone test.
Syntax	AT+TRSSI<CR>
Arguments	None
Response	<rssi_lvl><CR><LF>: value in dBm
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF>

Example

AT+TCONF – LoRa RF test configuration

Description	Sets/gets the LoRa RF test configuration.
Syntax	AT+TCONF=<freq>:<pow>:<bw>:<sf>:<cr>:<lna>:<pa>:<mod>:<paylen>:<freq dev>:<lowdropt>:<BT><CR> AT+TCONF=?<CR>

Arguments	• <freq>: frequency in Hz
	• <pow>: Tx power in range [-9:22] dBm
	• <bw>:
	– LoRa (in kHz)
	◦ 0: 7.8125
	◦ 1: 15.625
	◦ 2: 31.25
	◦ 3: 62.5
	◦ 4: 125
	◦ 5: 250
	◦ 6: 500
	–	FSK: 4800 to 467000 Hz
	• <sf>:
	– LoRa: SF5 to SF12 bit/s
	–	FSK: 600 to 300000 bit/s
	• <cr>: LoRa only
	–	1: 4/5
	–	2: 4/6
	–	3: 4/7
	–	4: 4/8
	• <lna>: low-noise amplifier – 0: Off
	–	1: On
	• <pa>: PA boost
	– 0: Off
	–	1: On
	• <mod>: modulation
	–	[0: FSK
	– 1: LoRa
	– 2: BPSK(Tx)
	• <paylen>: payload length 1 to 256
	• <freqdev>: FSK only 4800 to 467000
	• <lowdropt>: low DR optimization, LoRa only
	– 0: Off
	–	1: On
	– 2: Auto (1 when SF11 or SF12, 0 otherwise)
	• <BT>: FSK only
	– 0: no Gaussian filter applied
	–	1: BT = 0,3
	–	2: BT = 0,5
	–	3: BT = 0,7
	–	4: BT = 1

Response

• Freq= <freq> Hz<CR>

• Power= <pow> dBm<CR>

• Bandwidth= <bw> (=125000 Hz)<CR>

• SF= <sf><CR>

• CR= <cr> (=4/5)<CR>

• LNA State= <lna><CR>

• PA Boost State= <pa><CR>

• Modulation <mod><CR>

• Payload len= <paylen> Bytes<CR>

• <freqdev><CR>

• LowDRopt[0 to 2]= <lowdropt><CR>

• <BT><CR>

Result code

<CR><LF>AT_PARAM_ERROR<CR><LF>

Note: <pa>, <freqdev>, <lowdropt> and <BT> arguments are required by the command syntax but are not used on the B-L072Z-LRWAN1 platform.

Examples:

AT+TTX – Packets to be sent for PER RF TX test

Description	Starts a PER RF TX test with the number of packets to be sent.
Syntax	AT+TTX=<nb_packets><CR>
Arguments	<nb_packets>
Response	None
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF>

Example:

AT+TRX – Packets to be received for PER RF RX test

Description	Starts a PER RF RX test with the number of packets to be received.
Syntax	AT+TRX=<nb_packets><CR>
Arguments	<nb_packets>
Response	None
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF>

Example:

AT+TTH – RF Tx hopping test

Description	Starts RF Tx hopping test from Fstart to Fstop, with Fdelta steps.
Syntax	AT+TTH=<Fstart>,<Fstop>,<FDelta>,<nb_packets><CR>
Arguments	• <Fstart>: frequency start (in Hz or MHz) • <Fstop>: frequency stop (in Hz or MHz) • <FDelta>: frequency bandwidth (in Hz) • <nb_packets>: number of packets to be sent
Response	None
Result code	<CR><LF> OK <CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF> <CR><LF>AT_BUSY_ERROR<CR><LF>

Example:

AT+CERTIF – Module in LoRaWAN certification with join mode

Description	Starts the module in LoRaWAN certification and with the choice of join mode.
Syntax	AT+CERTIF=<mode><CR>
Arguments	<mode> 0: join to a network by ABP 1: join to a network by OTAA
Response	+EVT:JOINED +EVT:JOIN_FAILED
Result code	<CR><LF>OK<CR><LF> <CR><LF>AT_PARAM_ERROR<CR><LF>

Examples:

AT+TOFF – RF test

Description	Stops the RF test.
Syntax	AT+TOFF<CR>
Arguments	None
Response	None
Result code	<CR><LF>OK<CR><LF>

Example:

Information

AT+BAT – Battery level

Description	Gets the battery level (in mV).
Syntax	AT+BAT=?<CR>
Arguments	None
Response	<level><CR><LF>: value is in mV
Result code	<CR><LF>OK<CR><LF>

Example:

AT+TEMP – Temperature

Description	Gets the temperature of module (in Celsius degree °C).
Syntax	AT+TEMP=?<CR>
Arguments	None
Response	<Celsius degree><CR><LF>: value is in Celsius degree.
Result code	<CR><LF>OK<CR><LF>

Example:

Examples

Here are some basic examples that describe how to use the AT commands. In the following sections, commands provided by the host are preceded by #, and comments are embraced with /* */.

Join and send in unconfirmed mode

Join and send in the confirmed mode

Rx received data
It is possible to retrieve data sent from a specified port, when +EVT:RX is received.

Class B enables request
The example below shows how to do a Class B request through an AT command sequence.

Documents / Resources

STMICROELECTRONICS STM32L0 Ultra Low Power MCUs [pdf] User Manual
STM32L0 Ultra Low Power MCUs, STM32L0, Ultra Low Power MCUs, Low Power MCUs, Power MCUs

References

User Manual

STMICROELECTRONICS STM32L0 Ultra Low Power MCUs

Product Information

Product Usage Instructions

General information

Overview

AT commands

Examples

Documents / Resources

References

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