Application description
The Serial LTE Modem (SLM) application demonstrates how to use an nRF91 Series device as a stand-alone LTE modem that can be controlled by AT commands.
Overview
The nRF91 Series SiP integrates both a full LTE modem and an application MCU, enabling you to run your LTE application directly on the device.
However, if you want to run your application on a different chip and use the nRF91 Series device only as a modem, the serial LTE modem application provides you with an interface for controlling the LTE modem through AT commands.
The application accepts both the modem-specific AT commands and proprietary AT commands. The AT commands are documented in the following guides:
Modem-specific AT commands - nRF91x1 AT Commands Reference Guide and nRF9160 AT Commands Reference Guide
Proprietary AT commands - SLM-specific AT commands
Requirements
The application supports the following development kits:
Hardware platforms |
PCA |
Board name |
Board target |
---|---|---|---|
PCA20065 |
thingy91x |
|
|
PCA20035 |
thingy91 |
|
|
PCA10153 |
|
||
PCA10090 |
|
When built for a board target with the */ns
variant, the sample is configured to compile and run as a non-secure application with Cortex-M Security Extensions enabled.
Therefore, it automatically includes Trusted Firmware-M that prepares the required peripherals and secure services to be available for the application.
Configuration
See Configuring and building an application for information about how to permanently or temporarily change the configuration.
Configuration options
- CONFIG_SLM_CUSTOMER_VERSION - Customer version string
Version string defined by the customer after customizing the application. When defined, this version is reported with the baseline versions by the
#XSLMVER
AT command.
- CONFIG_SLM_AT_MAX_PARAM - AT command parameter count limit
This defines the maximum number of parameters allowed in an AT command, including the command name.
- CONFIG_SLM_CMUX - Enable CMUX functionality
This option is enabled by the CMUX overlay. It adds support for CMUX. See CMUX AT commands for more information.
- CONFIG_SLM_PPP - Enable PPP functionality
This option is enabled by the PPP overlay. It adds support for PPP. PPP can be used in conjunction with CMUX in order to use a single UART for both AT data and PPP. When CMUX is also enabled, PPP is usable only through a CMUX channel. See PPP AT commands for more information.
- CONFIG_SLM_NATIVE_TLS - Use Zephyr’s Mbed TLS for TLS connections
This option is enabled by the native TLS overlay. See Native TLS for more information.
- CONFIG_SLM_NATIVE_TLS_CREDENTIAL_BUFFER_SIZE - Buffer space reserved for loading credentials
Specifies the credential buffer size available for a single
sec_tag
when loading credentials for Mbed TLS. The default value is4096
.
- CONFIG_SLM_NATIVE_TLS_CREDENTIAL_BUFFER_COUNT - Number of buffers for loading credentials
The number of buffers available for loading
sec_tag
credentials for Mbed TLS. TLS client only needs the buffer when connecting, while TLS server needs the buffer as long as it is running. Increase the value if you need both TLS client and server running simultaneously with differentsec_tags
. The default value is1
.
- CONFIG_SLM_EXTERNAL_XTAL - Use external XTAL for UARTE
This option configures the application to use an external XTAL for UARTE. For the nRF9160 DK, see the nRF9160 Product Specification (section 6.19 UARTE) for more information. For the nRF9161 DK, see the nRF9161 Product Specification (section 6.19 UARTE) for more information.
- CONFIG_SLM_START_SLEEP - Enter sleep on startup
This option makes an nRF91 Series device enter deep sleep after startup. It is not enabled by default.
- CONFIG_SLM_POWER_PIN - Interface GPIO pin to power off the SiP and exit from sleep or idle
This option specifies which pin to use to power on or off the SiP and make SLM exit idle mode. It is set by default as follows:
On the nRF9161 DK:
P0.8 (Button 1 on the nRF9161 DK) is used when UART_0 is used.
P0.31 is used when UART_1 is used.
On the nRF9160 DK:
P0.6 (Button 1 on the nRF9160 DK) is used when UART_0 is used.
P0.31 is used when UART_1 is used.
On Thingy:91 and Thingy:91 X, P0.26 (Multi-function button) is used.
Note
This pin is configured with a pull up, so it is active low. It must be pulled down for a short time to perform one power off or wake up operation.
- CONFIG_SLM_INDICATE_PIN - Interface GPIO pin to indicate data available or unsolicited event notifications
This option specifies which pin to use for indicating data available or unsolicited event notifications from the modem. It is set by default as follows:
On the nRF9161 DK:
P0.00 (LED 1 on the nRF9161 DK) is used when UART_0 is selected.
P0.30 is used when UART_2 is selected.
On the nRF9160 DK:
P0.2 (LED 1 on the nRF9160 DK) is used when UART_0 is selected.
P0.30 is used when UART_2 is selected.
It is not defined when the targets are Thingy:91 and Thingy:91 X.
Note
This pin is configured to be active low, so it will be high when inactive.
- CONFIG_SLM_INDICATE_TIME - Indicate GPIO active time
This option specifies the length, in milliseconds, of the time interval during which the indicate GPIO must stay active. The default value is 100 milliseconds.
- CONFIG_SLM_AUTO_CONNECT - Connect to LTE network at start-up or reset
This option enables connecting to the LTE network at start-up or reset using a defined PDN configuration. This option is enabled by the LwM2M Carrier overlay, but is otherwise disabled by default.
Note
This option requires network-specific configuration in the
slm_auto_connect.h
file.Here is a sample configuration for NIDD connection in the
slm_auto_connect.h
file:/* Network-specific default system mode configured by %XSYSTEMMODE (refer to AT command manual) */ 0, /* LTE support */ 1, /* NB-IoT support */ 0, /* GNSS support, also define CONFIG_MODEM_ANTENNA if not Nordic DK */ 0, /* LTE preference */ /* Network-specific default PDN configured by +CGDCONT and +CGAUTH (refer to AT command manual) */ true, /* PDP context definition required or not */ "Non-IP", /* PDP type: "IP", "IPV6", "IPV4V6", "Non-IP" */ "", /* Access point name */ 0, /* PDP authentication protocol: 0(None), 1(PAP), 2(CHAP) */ "", /* PDN connection authentication username */ "" /* PDN connection authentication password */
- CONFIG_SLM_CR_TERMINATION - CR termination
This option configures the application to accept AT commands ending with a carriage return.
Select this option if you want to connect to the development kit using PuTTY. See Testing and optimization for instructions.
- CONFIG_SLM_LF_TERMINATION - LF termination
This option configures the application to accept AT commands ending with a line feed.
- CONFIG_SLM_CR_LF_TERMINATION - CR+LF termination
This option configures the application to accept AT commands ending with a carriage return followed by a line feed.
- CONFIG_SLM_TCP_POLL_TIME - Poll timeout in seconds for TCP connection
This option specifies the poll timeout for the TCP connection, in seconds.
- CONFIG_SLM_SMS - SMS support in SLM
This option enables additional AT commands for using the SMS service.
- CONFIG_SLM_GNSS - GNSS support in SLM
This option enables additional AT commands for using the GNSS service.
- CONFIG_SLM_NRF_CLOUD - nRF Cloud support in SLM
This option enables additional AT commands for using the nRF Cloud service.
- CONFIG_SLM_FTPC - FTP client support in SLM
This option enables additional AT commands for using the FTP client service.
- CONFIG_SLM_TFTPC - TFTP client support in SLM
This option enables additional AT commands for using the TFTP client service.
- CONFIG_SLM_MQTTC - MQTT client support in SLM
This option enables additional AT commands for using the MQTT client service.
- CONFIG_SLM_MQTTC_MESSAGE_BUFFER_LEN - Size of the buffer for the MQTT library
This option specifies the maximum message size which can be transmitted or received through MQTT (excluding PUBLISH payload). The default value is 512, meaning 512 bytes for TX and RX, respectively.
- CONFIG_SLM_HTTPC - HTTP client support in SLM
This option enables additional AT commands for using the HTTP client service.
- CONFIG_SLM_TWI - TWI support in SLM
This option enables additional AT commands for using the TWI service.
- CONFIG_SLM_UART_RX_BUF_COUNT - Receive buffers for UART.
This option defines the number of buffers for receiving (RX) UART traffic. The default value is 3.
- CONFIG_SLM_UART_RX_BUF_SIZE - Receive buffer size for UART.
This option defines the size of a single buffer for receiving (RX) UART traffic. The default value is 256.
- CONFIG_SLM_UART_TX_BUF_SIZE - Send buffer size for UART.
This option defines the size of the buffer for sending (TX) UART traffic. The default value is 256.
Additional configuration
To save power, both the console and the output logs over UART_0
are disabled in this application.
This information is logged using RTT instead.
See Testing and optimization for instructions on how to view this information.
To switch to UART output, change the following options in the prj.conf
file:
# Segger RTT
CONFIG_USE_SEGGER_RTT=n
CONFIG_RTT_CONSOLE=n
CONFIG_UART_CONSOLE=y
CONFIG_LOG_BACKEND_RTT=n
CONFIG_LOG_BACKEND_UART=y
Configuration files
You can find the configuration files in the applications/serial_lte_modem
directory.
In general, they have an overlay-
prefix, and a .conf
or .overlay
extension for Kconfig or devicetree overlays, respectively.
Board-specific configuration files are named <BOARD>
with a .conf
or .overlay
extension and are located in the boards
directory.
When the name of the board-specific configuration file matches the board target, the overlay is automatically included by the build system.
See Build and configuration system: for more information on the nRF Connect SDK configuration system.
Important
When adding Kconfig fragments and devicetree overlays, make sure to use the -DEXTRA_CONF_FILE
and -DEXTRA_DTC_OVERLAY_FILE
CMake parameters, respectively.
Otherwise, if -DCONF_FILE
or -DDTC_OVERLAY_FILE
is used, all the configuration files that normally get picked up automatically will have to be included explicitly.
The following configuration files are provided:
prj.conf
- This configuration file contains the standard configuration for the serial LTE modem application and is included by default by the build system.overlay-native_tls.conf
- This configuration file contains additional configuration options that are required to use Native TLS. You can include it by adding-DEXTRA_CONF_FILE=overlay-native_tls.conf
to your build command. See Providing CMake options.overlay-carrier.conf
- Configuration file that adds nRF Connect SDK LwM2M carrier support. See Using the LwM2M carrier library for more information on how to connect to an operator’s device management platform.overlay-full_fota.conf
- Configuration file that adds full modem FOTA support. See FOTA AT commands for more information on how to use full modem FOTA functionality.overlay-cmux.conf
- Configuration file that adds support for the CMUX protocol. See CMUX AT commands for more information.overlay-ppp.conf
- Configuration file that adds support for the Point-to-Point Protocol (PPP). This disables most of the IP-based protocols available through AT commands (such as FTP and MQTT) as it is expected that the controlling chip’s own IP stack is used instead. See CONFIG_SLM_PPP and PPP AT commands for more information.overlay-ppp-without-cmux.conf
- Kconfig fragment that configures the UART to be used by PPP. This configuration file should be included when building SLM with PPP and without CMUX.overlay-ppp-without-cmux.overlay
- Devicetree overlay that configures the UART to be used by PPP. This configuration file should be included when building SLM with PPP and without CMUX, in addition tooverlay-ppp.conf
. It can be customized to fit your configuration (UART, baud rate, and so on). By default, it sets the baud rate of the PPP UART to 1 000 000.overlay-zephyr-modem.conf
,overlay-zephyr-modem-external-mcu.conf
,overlay-zephyr-modem-nrf9160dk-nrf52840.conf
,overlay-external-mcu.overlay
, andoverlay-zephyr-modem-nrf9160dk-nrf52840.overlay
- These configuration files are used when compiling SLM to turn an nRF91 Series SiP into a Zephyr-compatible standalone modem. See nRF91 Series as a Zephyr-compatible modem for more information.boards/nrf9160dk_nrf9160_ns.conf
- Configuration file specific for the nRF9160 DK. This file is automatically merged with theprj.conf
file when you build for thenrf9160dk/nrf9160/ns
board target.boards/nrf9161dk_nrf9161_ns.conf
- Configuration file specific for the nRF9161 DK. This file is automatically merged with theprj.conf
file when you build for thenrf9161dk/nrf9161/ns
board target.boards/thingy91_nrf9160_ns.conf
- Configuration file specific for Thingy:91. This file is automatically merged with theprj.conf
file when you build for thethingy91/nrf9160/ns
board target.boards/thingy91x_nrf9151_ns.conf
- Configuration file specific for Thingy:91 X. This file is automatically merged with theprj.conf
file when you build for thethingy91x/nrf9151/ns
board target.
Native TLS
By default, the secure socket (TLS) is offloaded to the modem. If you need customized TLS features that are not supported by the modem firmware, you can use native TLS instead. Native TLS uses the Mbed TLS library in Zephyr to establish secure connectivity. Currently, the SLM application can be built to use native TLS for the following services:
Secure socket
TLS Proxy client
TLS Proxy server
HTTPS client
With native TLS, the credentials are stored in the Zephyr settings storage with the AT#XCMNG
command.
The configuration options that are required to enable native TLS are defined in the overlay-native_tls.conf
file.
Note
Native TLS services have the following limitations:
TLS session resumption is currently not supported.
Sending traces over UART on an nRF91 Series DK
To send modem traces over UART on an nRF91 Series DK, configuration must be added for the UART device in the devicetree and Kconfig. This is done by adding the modem trace UART snippet when building and programming.
Use the Cellular Monitor app for capturing and analyzing modem traces.
TF-M logging must use the same UART as the application. For more details, see shared TF-M logging.
Building and running
This sample can be found under applications/serial_lte_modem
in the nRF Connect SDK folder structure.
When built as firmware image for a board target with the */ns
variant, the sample has Cortex-M Security Extensions (CMSE) enabled and separates the firmware between Non-Secure Processing Environment (NSPE) and Secure Processing Environment (SPE).
Because of this, it automatically includes the Trusted Firmware-M (TF-M).
To read more about CMSE, see Processing environments.
To build the sample, follow the instructions in Configuring and building an application for your preferred building environment. See also Programming an application for programming steps and Testing and optimization for general information about testing and debugging in the nRF Connect SDK.
Note
When building repository applications in the SDK repositories, building with sysbuild is enabled by default.
If you work with out-of-tree freestanding applications, you need to manually pass the --sysbuild
parameter to every build command or configure west to always use it.
Communicating with the modem on an nRF91 Series DK
In this scenario, an nRF91 Series DK running the Serial LTE Modem application serves as the host. You can use either a PC or an external MCU as a client.
Connecting with a PC
To connect to an nRF91 Series DK with a PC:
Verify that
UART_0
is selected in the application. It is defined in the default configuration.Use nRF Connect Serial Terminal to connect to the development kit. See Testing and optimization for instructions. You can also use the Open Serial Terminal option of the Cellular Monitor app to open the Serial Terminal. Using the Cellular Monitor app in combination with the nRF Connect Serial Terminal shows how the modem responds to the different modem commands. You can then use this connection to send or receive AT commands over UART, and to see the log output of the development kit.
Instead of using nRF Connect Serial Terminal, you can use PuTTY to establish a terminal connection to the development kit, using the default serial port connection settings.
Note
The default AT command terminator is a carriage return followed by a line feed (
\r\n
). nRF Connect Serial Terminal supports this format. If you want to use another terminal emulator, make sure that the configured AT command terminator corresponds to the line terminator of your terminal. When using PuTTY, you must set the CONFIG_SLM_CR_TERMINATION SLM configuration option. See Configuration options for more details.
Connecting with an external MCU
Note
This section does not apply to Thingy:91 or Thingy:91 X.
If you run your user application on an external MCU (for example, an nRF52 Series development kit), you can control the modem on an nRF91 Series device directly from the application. See the Cellular: SLM Shell for a sample implementation of such an application.
To connect with an external MCU using UART_2, change the configuration files for the default board as follows:
In the
nrf9161dk_nrf9161_ns.conf
file:# Use UART_0 (when working with PC terminal) # unmask the following config #CONFIG_UART_0_NRF_HW_ASYNC_TIMER=2 #CONFIG_UART_0_NRF_HW_ASYNC=y #CONFIG_SLM_POWER_PIN=8 #CONFIG_SLM_INDICATE_PIN=0 # Use UART_2 (when working with external MCU) # unmask the following config CONFIG_UART_2_NRF_HW_ASYNC_TIMER=2 CONFIG_UART_2_NRF_HW_ASYNC=y CONFIG_SLM_POWER_PIN=31 CONFIG_SLM_INDICATE_PIN=30
In the
nrf9161dk_nrf9161_ns.overlay
file:/ { chosen { ncs,slm-uart = &uart2; } }; &uart0 { status = "disabled"; }; &uart2 { compatible = "nordic,nrf-uarte"; current-speed = <115200>; status = "okay"; hw-flow-control; pinctrl-0 = <&uart2_default_alt>; pinctrl-1 = <&uart2_sleep_alt>; pinctrl-names = "default", "sleep"; };
In the
nrf9160dk_nrf9160_ns.conf
file:# Use UART_0 (when working with PC terminal) # unmask the following config #CONFIG_UART_0_NRF_HW_ASYNC_TIMER=2 #CONFIG_UART_0_NRF_HW_ASYNC=y #CONFIG_SLM_POWER_PIN=6 #CONFIG_SLM_INDICATE_PIN=2 # Use UART_2 (when working with external MCU) # unmask the following config CONFIG_UART_2_NRF_HW_ASYNC_TIMER=2 CONFIG_UART_2_NRF_HW_ASYNC=y CONFIG_SLM_POWER_PIN=31 CONFIG_SLM_INDICATE_PIN=30
In the
nrf9160dk_nrf9160_ns.overlay
file:/ { chosen { ncs,slm-uart = &uart2; } }; &uart0 { status = "disabled"; }; &uart2 { compatible = "nordic,nrf-uarte"; current-speed = <115200>; status = "okay"; hw-flow-control; pinctrl-0 = <&uart2_default_alt>; pinctrl-1 = <&uart2_sleep_alt>; pinctrl-names = "default", "sleep"; };
The following table shows how to connect an nRF52 Series development kit to an nRF91 Series development kit to be able to communicate through UART:
nRF52 Series DK |
nRF91 Series DK |
---|---|
UART TX P0.6 |
UART RX P0.11 |
UART RX P0.8 |
UART TX P0.10 |
UART CTS P0.7 |
UART RTS P0.12 |
UART RTS P0.5 |
UART CTS P0.13 |
GPIO OUT P0.27 |
GPIO IN P0.31 |
GPIO IN P0.26 |
GPIO OUT P0.30 |
Use the following UART devices:
nRF52840 or nRF52832 - UART0
nRF9160 or nRF9161 - UART2
Use the following UART configuration:
Hardware flow control: enabled
Baud rate: 115200
Parity bit: no
Operation mode: IRQ
Note
The GPIO output level on the nRF91 Series device side must be 3 V. You can set the VDD voltage with the VDD IO switch (SW9). See the VDD supply rail section in the nRF9160 DK User Guide for more information related to nRF9160 DK.
Communicating with the modem on Thingy:91
In this scenario, Thingy:91 running the Serial LTE Modem application serves as the host. You can use a PC as a client.
Connecting with a PC
The nRF52840 SoC of Thingy:91 is pre-programmed with the Connectivity bridge application.
To update the Connectivity bridge application, see the Updating the Thingy:91 firmware using Programmer documentation.
The Connectivity bridge application routes UART_0
to USB_CDC0
on Thingy:91.
By enabling the CONFIG_BRIDGE_BLE_ENABLE
Kconfig option in the Connectivity bridge, you can also use SLM over Nordic UART Service (NUS).
To connect to a Thingy:91 with a PC:
Verify that
UART_0
is selected in the application. It is defined in the default configuration.Use nRF Connect Serial Terminal to connect to the development kit. See Testing and optimization for instructions. You can also use the Open Serial Terminal option of the Cellular Monitor app to open the Serial Terminal. Using the Cellular Monitor app in combination with the nRF Connect Serial Terminal shows how the modem responds to the different modem commands. You can then use this connection to send or receive AT commands over UART, and to see the log output of the development kit.
Instead of using nRF Connect Serial Terminal, you can use PuTTY to establish a terminal connection to the development kit, using the default serial port connection settings.
Note
The default AT command terminator is a carriage return followed by a line feed (
\r\n
). nRF Connect Serial Terminal supports this format. If you want to use another terminal emulator, make sure that the configured AT command terminator corresponds to the line terminator of your terminal. When using PuTTY, you must set the CONFIG_SLM_CR_TERMINATION SLM configuration option. See Configuration options for more details.
You can also test the i2c sensor on Thingy:91 using TWI AT commands. See TWI AT commands for more details.
Testing
The following testing instructions focus on testing the application with a PC client. If you have an nRF52 Series DK running a client application, you can also use this DK for testing the different scenarios.
After programming the sample to your development kit, complete the following steps to test it:
Connect the kit to the computer using a USB cable. The kit is assigned a COM port (Windows) or ttyACM device (Linux), which is visible in the Device Manager.
Connect to the kit with nRF Connect Serial Terminal. You can also use the Open Serial Terminal option of the Cellular Monitor app to open the Serial Terminal. If you want to use a different terminal emulator, see Connecting with a PC.
Reset the kit.
Observe that the development kit sends a
Ready\r\n
message on UART.Send AT commands and observe the responses from the development kit.
See Testing scenarios for typical test cases.
Using the LwM2M carrier library
The application supports the nRF Connect SDK LwM2M carrier library that you can use to connect to the operator’s device management platform. See the library’s documentation for more information and configuration options.
To enable the LwM2M carrier library, add the parameter -DOVERLAY_CONFIG=overlay-carrier.conf
to your build command.
The CA root certificates that are needed for modem FOTA are not provisioned in the Serial LTE Modem application. You can flash the Cellular: LwM2M carrier sample to write the certificates to modem before flashing the Serial LTE Modem application, or use the Cellular: AT Client sample as explained in preparing the Cellular: LwM2M Client sample for production. It is also possible to modify the Serial LTE Modem application project itself to include the certificate provisioning, as demonstrated in the Cellular: LwM2M carrier sample.
int lwm2m_carrier_event_handler(const lwm2m_carrier_event_t *event)
{
switch (event->type) {
case LWM2M_CARRIER_EVENT_INIT:
carrier_cert_provision();
...
The certificate provisioning can also be done directly in the Serial LTE Modem application by using the same AT commands as described for the Cellular: AT Client sample.
When the LwM2M carrier library is in use, by default the application will auto-connect to the network on startup.
This behavior can be changed by disabling the CONFIG_SLM_AUTO_CONNECT
option.
Dependencies
This application uses the following nRF Connect SDK libraries:
It uses the following sdk-nrfxlib libraries:
In addition, it uses the following secure firmware component: