Cellular Device-to-Cloud Data Pump
Affordable, embeddable module for low-power cellular connectivity.
Modern industrial and commercial systems increasingly need to securely send data to the cloud, and often enable remote control, as well. These requirements require greenfield or retrofit designs to adapt existing systems to this new operating reality.
The growing danger of connecting devices to the internet using Wi-Fi, combined with the increasing need to track assets while in-motion, has generated tremendous interest in cellular as an alternative for safe and reliable transport of data between devices and the cloud.
To date, however, cellular communications have been equated with high cost, power-hungry devices, and high implementation complexity for hardware and software developers alike.
Functional Description
As an embeddable device-to-cloud data pump, the Notecard eliminates all complexity and friction that exists with existing IoT solutions. It enables development and rapid iteration of production-quality secure cellular, Wi-Fi, or LoRa IoT solutions at an extremely low, fixed cost. With as little as two lines of code on the controlling MCU, and with no external libraries or dependencies, data can be sent from device to cloud.
Notecard is:
- A drop-in embeddable data storage and transport module for cellular IoT
products, pumping JSON-formatted or binary data ("Notes") bi-directionally
between device and cloud:
- JSON from/to MCU application using I2C, Serial, or USB.
- JSON to/from your cloud app using HTTPS or MQTT.
- JSON is auto-tagged with date/time, tower, and GPS locations.
- A removable and field-upgradable 30mm x 35-42mm system-on-a-module (SOM).
- A cellular device without the monthly fees.
Features
- Low-power. Designed to operate on battery power, be "always-on", maintain time & location, while typically drawing less than ~8µA@5V when idle.
- MCU-agnostic. Will support any MCU or single-board computer as your app processor - even low-memory, 8-bit microcontrollers.
- Global. With both narrowband and wideband modems tailored for use in North America or globally, a Notecard can connect in almost any location. See Cellular Service for details.
Decoding Notecard SKUs
Each cellular-based Notecard is supplied a SKU in the format of "NOTE-XXXXX". The following table shows how to decode the differences in Notecard SKUs.
Example: | NOTE- | WB | GL | W | T |
---|---|---|---|---|---|
Bands WB = Wideband (Cat-1) MB = Midband (Cat-1 bis) NB = Narrowband (LTE-M/NB-IoT) | ⬅️ | ||||
Region GL = Global NA = North America EX = EMEA | ⬅️ | ||||
Wi-Fi W = Includes Wi-Fi N or blank = Cellular only | ⬅️ | ||||
Modem T = Has a Telit modem Blank = See tables below for modem | ⬅️ |
Legacy Notecard Cellular SKUs have additional characters to denote the
500MB of data included, e.g. -500
.
Wideband (LTE Cat-1 Notecards)
SKU | General Region | Bands | Data Networks | Modem | Wi-Fi |
---|---|---|---|---|---|
NOTE-WBEX-500 | EX - EMEA (Europe, Middle East, Africa) | WB - Wideband | LTE Cat-1 / WCDMA / GPRS | Quectel EG91-EX | No |
NOTE-WBEXN | EX - EMEA (Europe, Middle East, Africa) | WB - Wideband | LTE Cat-1 / WCDMA / GPRS | Quectel EG91-EX | No |
NOTE-WBEXW | EX - EMEA (Europe, Middle East, Africa) | WB - Wideband | LTE Cat-1 / WCDMA / GPRS | Quectel EG91-EX | Yes |
NOTE-WBGLWT (previously NOTE-WBGLW) | GL - Global | WB - Wideband | LTE Cat-1 / WCDMA / GPRS | Telit LE910C1-WWXD | Yes |
NOTE-WBNA-500 | NA - North America | WB - Wideband | LTE Cat-1 / WCDMA | Quectel EG91-NAX | No |
NOTE-WBNAN | NA - North America | WB - Wideband | LTE Cat-1 / WCDMA | Quectel EG91-NAX | No |
NOTE-WBNAW | NA - North America | WB - Wideband | LTE Cat-1 / WCDMA | Quectel EG91-NAXD | Yes |
See Cellular Band Support for Wideband Notecards
Midband (LTE Cat-1 bis Notecards)
SKU | General Region | Bands | Data Networks | Modem | Wi-Fi |
---|---|---|---|---|---|
NOTE-MBGLN | GL - Global | MB - Midband | LTE Cat-1 bis | Quectel EG916Q-GL | No |
NOTE-MBGLW | GL - Global | MB - Midband | LTE Cat-1 bis | Quectel EG916Q-GL | Yes |
NOTE-MBNAN | NA - North America | MB - Midband | LTE Cat-1 bis | Quectel EG915Q-NA | No |
NOTE-MBNAW | NA - North America | MB - Midband | LTE Cat-1 bis | Quectel EG915Q-NA | Yes |
See Cellular Band Support for Midband Notecards
Narrowband (LTE-M/NB-IoT Notecards)
SKU | General Region | Bands | Data Networks | Modem | Wi-Fi |
---|---|---|---|---|---|
NOTE-NBGL-500 | GL - Global | NB - Narrowband | LTE-M / NB-IoT / GPRS | Quectel BG95-M3 | No |
NOTE-NBGLN | GL - Global | NB - Narrowband | LTE-M / NB-IoT / GPRS | Quectel BG95-M3 | No |
NOTE-NBGLW | GL - Global | NB - Narrowband | LTE-M / NB-IoT / GPRS | Quectel BG95-M3 | Yes |
NOTE-NBNA-500 | NA - North America | NB - Narrowband | LTE-M | Quectel BG95-M1 | No |
NOTE-NBNAN | NA - North America | NB - Narrowband | LTE-M | Quectel BG95-M1 | No |
NOTE-NBNAW | NA - North America | NB - Narrowband | LTE-M | Quectel BG95-M1 | Yes |
See Cellular Band Support for Narrowband Notecards
- Hassle-free. The integrated, embedded MFF2 SIM features both North American and Global coverage options. No SIM or carrier subscription is required. Includes 10-years of global cellular service with 500MB of data (more data options available upon request).
- Connected. Provides connectivity without the hassle of dealing with SSIDs, passwords, access points, gateways, carriers, or SIMs.
- Secure. Integrated STSAFE Secure Element with hardware crypto, true hardware random number generator, and a factory-installed ECC P-384 certificate provisioned at chip manufacture.
- Simple. Uses a JSON command interface over I2C, UART, or USB. Allows you to connect your 3.3V or 1.8V MCU, while eliminating complex AT commands and state to manage.
- Power-conscious. Integrated GPS with LIS2DTW accelerometer, for power-optimized location/motion awareness. Not to mention a mostly-offline data sync mode for low power, and always-online mode for low latency.
- Encrypted. Secures transactions without any provisioning challenges, using encrypted "off the internet" communication.
- Efficient. Battery-powered cellular without the complexity of managing modems, connections, queues, or storage.
- Integrated. Utilizes an extremely thin cloud infrastructure that directly routes your data to where it belongs: AWS, Azure, GCP, or your own cloud.
- Built for data. Data routing and simple "no code/low code" visual data stream analysis through Notehub.io (SaaS), or host and integrate Notehub functionality into your own app (OSS).
The performance of the STM32 microcontroller onboard the Notecard may be affected in the presence of extremely bright light including, for example, direct sunlight. Bright light may interfere with the semiconductor's operation by generating unwelcome electrical currents, performance degradation, malfunction, or shutdown.
If you anticipate that bright light may shine on your Notecard in its deployed setting, we recommend you mount the Notecard in a shadow, or that you cover the STM32 microcontroller with an opaque tape to reduce light levels that may affect the semiconductor.
Package Configuration
NOTE-WBNA-500 - Notecard, Wideband, North America, 500MB
- Product Name: Notecard Cellular (Legacy)
- Modem: Quectel EG91-NAX
- Data Networks: LTE Cat-1 / WCDMA
- General Region: North America (United States, Canada, and Mexico)
- Data included: 500MB
Modem Datasheet
To best determine the supported bands and radio access technologies, RATs, refer to the modem datasheet.
Block Diagram
The Cellular Notecard is packaged using a compact removable form factor, 30mm x 35mm.
Open hardware schematics for both the Notecard and Notecarrier boards are available on GitHub, making it a straightforward task to embed the Notecard into a broad variety of host device designs.
The Notecard has an embedded MFF2 SIM that enables its included cellular service coverage, with an integrated external SIM switch for applications that require such a capability.
The Notecard can interface with the host MCU at either 1.8v or 3.3v levels.
Typical Application
As shown below, Notecard is not an application processor and hosts no customer application code. It can be used as a data pump peripheral that is focused on bidirectional, asynchronous, secure data staging and transfer of JSON Notes. The Notecard can also be configured as a low powered, autonomous, asset tracking device, in which case it does not require a host processor.
Key Features
-
Tracking
Notes transferred by the Notecard can be tagged with time and location. Location is obtained using a GPS receiver, and time is available from both the cellular network and GPS. To optimize energy use in devices when not in motion, the Notecard has a MEMS-based, LIS2DTW accelerometer that determines when use of the GPS is not required.
-
Security
Modern services require that the cloud and the device perform bidirectional authentication so that neither can be spoofed. For many applications it's important that over-the-air and over-the-wire data is encrypted. For this reason, the Notecard integrates an STSAFE Secure Element which contains symmetric keys manufactured into the chip. Neither the manufacturer of the Notecard nor the manufacturer of the customer's product has any need to handle or manage secure key material. The keys generated by STMicroelectronics for the Notecard use ECC with the NIST P-384 curve, and the signature algorithm is ECDSA-with-SHA384.
-
Low Power Consumption
The Notecard has sophisticated power control and makes heavy use of variable clock speeds. This enables the Notecard to have a typical idle current consumption of ~8µA@5V, while still supporting active UART and I2C communication.
Power Information
The Notecard's main supply voltage (VMODEM_P
) is used for the cellular modem
and associated circuitry. The Notecard has on-board regulators designed for
direct connection to a battery, so any voltage in the range of 2.5V to 5.5V may
be provided.
The Notecard typically sits in an ~8µA@5V idle mode waiting for a request
from the host MCU, however the Notecard current draw increases to the ~250mA
range when the modem is active. Furthermore, when in a region requiring the use
of GSM, it can spike to up to nearly 2A for a few milliseconds. The modem also
draws 10's of mA when the GPS is receiving or the CPU is performing session
encryption. As such, it's recommended that VMODEM_P
be directly connected to a
battery or other supply that is capable of such brief spikes. It is also
recommended that PCB traces for VMODEM_P
and GND
be designed to handle such
current.
The Notecard's logic voltage (VIO_P
) is provided by the Notecarrier or host
system for digital communication; it will be either 1.8V or 3.3V. Although the
Notecard typically draws very little current, this supply should be designed
with a 150mA budget allocated to the Notecard.
Pin Name | Direction | Pin Numbers | Usage |
---|---|---|---|
GND | -- | 3,5,6,11,18,33,39,45,51,57,71,73 | Ground |
VIO_P | IN | 2,4 | 1.8V or 3.3V @ 150mA |
VUSB | IN | 13 | USB Serial proxy for "line power", with respect to dynamic line voltage detection |
VMODEM_P | IN | 70,72,74 | 2.5V to 5.5V, capable of sustained 750mA draw |
In order to take advantage of various Notecard features pertaining to "dynamic
line voltage detection" (both now and in the future), or establish a USB Serial
connection to the Notecard, you must connect the VUSB
power pin and support
the USB power design aspects of the Notecard.
Features include:
- Continuous mode behavior with the
usb
flag. - Triangulate mode behavior with the
usb
flag. - Monitor mode behavior.
Antenna Requirements
The Notecard requires a cellular antenna. The antenna should support the entire range of LTE bands in use in the region of deployment.
All versions of the Cellular Notecard require only a single LTE antenna, though
Wideband Notecards can improve their receiving sensitivity through a second
antenna on the DIV
u.FL connector.
The NOTE-WBNA-500 is a "wideband" version of the Notecard which optionally supports a second diversity antenna for maximum range when using LTE Cat-1.
Actual RF performance of the Notecard depends on a variety of physical factors, including:
- The choice of antenna(s).
- The physical environment.
- The trace layout, dimensions, and/or PCB tolerance of the carrier board (e.g. Notecarrier) used.
If an application utilizes GPS location, a GPS antenna is also required.
The Notecard design allows the option of a passive or active GPS antenna, and
can supply a 3.3V - 4.0V bias voltage to power an active antenna's LNA. If an
active antenna requires a different voltage, the board designer can inject
whatever voltage they require into the antenna's coax by feeding it to the
VACT_GPS_IN
pin.
Active GPS
If you choose to connect an Active GPS antenna to the Notecard GPS u.fl
connector, you are required to provide your antenna's DC bias voltage to the
center conductor of the coax antenna via VACT_GPS_IN
. For your convenience and
the Notecard supplies a 3.3V - 4.0V power supply at VACT_GPS_OUT
whenever it
activates its GPS, so VACT_GPS_OUT
can be connected directly to VACT_GPS_IN
.
VACT_GPS_OUT
must not be used for any other purpose than powering an active
antenna Low-Noise Amplifier.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
VACT_GPS_IN | IN | 22 | Active GPS antenna DC bias voltage |
VACT_GPS_OUT | OUT | 20 | +3.3V - 4.0V from Notecard when GPS is operating |
Cellular Service
A 10-year data plan with 500MB of cellular data is embedded in the Notecard, with more available for applications requiring it. No other actions related to cellular activation or deactivation are required. There are no "know your customer" restrictions, so the Notecard can be embedded in a product without knowing the ultimate end-customer. Placement of a product can be permanent. Although the coverage area may change from time to time because of local technical and regulatory restrictions.
Covered Countries
To approximately forecast the Notecard's compatibility with a country, you can research the networks available (for example on Wikipedia) and cross-reference with the modem datasheet.
This list of covered countries does not imply any widespread deployment or national coverage. Carrier agreements change over time. This list is for planning purposes only - we have not independently verified coverage.
If your experience differs please let us know so we can keep this list updated.
Covered Countries | ||
---|---|---|
United States | Canada | Mexico |
Cellular Band Support by SKU
Wideband Bands (LTE Cat-1 Notecards)
SKU | Modem | LTE Cat-1 | WCDMA (3G) | GSM/EDGE (2G) |
---|---|---|---|---|
NOTE‑WBEX‑500 | Quectel EG91‑EX | B1, B3, B7, B8, B20, B28 | B1, B8 | 900, 1800 MHz |
NOTE‑WBEXN | Quectel EG91‑EX | B1, B3, B7, B8, B20, B28 | B1, B8 | 900, 1800 MHz |
NOTE‑WBEXW | Quectel EG91‑EX | B1, B3, B7, B8, B20, B28 | B1, B8 | 900, 1800 MHz |
NOTE‑WBGLWT | Telit LE910C1‑WWXD | B1, B2, B3, B4, B5, B7, B8, B8_US, B9, B12, B13, B14, B18, B19, B20, B25, B26, B28 | B1, B2, B4, B5, B6, B8, B19 | B2, B3, B5, B8 |
NOTE‑WBNA‑500 | Quectel EG91‑NAX | B2, B4, B5, B12, B13, B25, B26 | B2, B4, B5 | |
NOTE‑WBNAN | Quectel EG91‑NAX | B2, B4, B5, B12, B13, B25, B26 | B2, B4, B5 | |
NOTE‑WBNAW | Quectel EG91‑NAXD | B2, B4, B5, B12, B13, B25, B26 | B2, B4, B5 |
Midband Bands (LTE Cat-1 bis Notecards)
SKU | Modem | LTE Cat-1 bis |
---|---|---|
NOTE‑MBGLN | Quectel EG916Q-GL | B1, B2, B3, B4, B5, B7, B8, B12, B13, B18, B19, B20, B25, B26, B28, B34, B38, B39, B40, B41, B66 |
NOTE‑MBGLW | Quectel EG916Q-GL | B1, B2, B3, B4, B5, B7, B8, B12, B13, B18, B19, B20, B25, B26, B28, B34, B38, B39, B40, B41, B66 |
NOTE‑MBNAN | Quectel EG915Q-NA | B2, B4, B5, B12, B13, B66 |
NOTE‑MBNAW | Quectel EG915Q-NA | B2, B4, B5, B12, B13, B66 |
Narrowband Bands (LTE-M/NB-IoT Notecards)
SKU | Modem | LTE-M | NB-IoT | GSM/EDGE (2G) |
---|---|---|---|---|
NOTE‑NBGL‑500 | Quectel BG95‑M3 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B28, B66, B71, B85 | 850, 900, 1800, 1900 MHz |
NOTE‑NBGLN | Quectel BG95‑M3 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B28, B66, B71, B85 | 850, 900, 1800, 1900 MHz |
NOTE‑NBGLW | Quectel BG95‑M3 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B28, B66, B71, B85 | 850, 900, 1800, 1900 MHz |
NOTE‑NBNA‑500 | Quectel BG95‑M1 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 | ||
NOTE‑NBNAN | Quectel BG95‑M1 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 | ||
NOTE‑NBNAW | Quectel BG95‑M1 | B1, B2, B3, B4, B5, B8, B12, B13, B18, B19, B20, B25, B26, B27, B28, B66, B85 |
Pin Information
Pin Definitions
Pin Name | Pin Description |
---|---|
ATTN_P | Attention pin (requires protection) |
AUX_EN_P | Auxiliary serial port enable (requires protection) |
AUX_RX_P | Auxiliary UART receive (requires protection) |
AUX_TX_P | Auxiliary UART transmit (requires protection) |
AUX1 | Auxiliary GPIO pin 1 |
AUX2 | Auxiliary GPIO pin 2 |
AUX3 | Auxiliary GPIO pin 3 |
AUX4 | Auxiliary GPIO pin 4 |
AUX5 | Alt. attention pin or charge detection |
GND | Ground |
NC | No connection (reserved and must be left open) |
NRST | Active-low (not) reset |
RX_P | UART receive (requires protection - Notecard has onboard 10K pull-up resistors) |
SCL_P | I2C clock (requires protection - Notecard has onboard 10K pull-up resistors) |
SDA_P | I2C data (requires protection - Notecard has onboard 10K pull-up resistors) |
SIM_CLK | External SIM clock |
SIM_IO | External SIM input/output |
SIM_NPRESENT | External SIM active-low (not) present |
SIM_RST | External SIM reset |
SIM_VCC | External SIM positive (common collector) voltage |
TX_P | UART transmit (requires protection) |
USB_DN | USB data negative |
USB_DP | USB data positive |
VACT_GPS_IN | Active antenna GPS bias voltage |
VACT_GPS_OUT | Active antenna GPS 3.8V from Notecard |
VIO_P | I/O Voltage (requires protection) |
VMODEM_P | Voltage modem (requires protection) |
VUSB | 5V USB voltage |
Pin Description
Notecard M.2 Key E, Edge Connector Pinout
Pin # | Pin Name | Func. Interface | Func. Interface | Pin Name | Pin # |
---|---|---|---|---|---|
1 | NC | Power | VIO_P | 2 | |
3 | GND | Power | Power | VIO_P | 4 |
5 | GND | Power | Power | GND | 6 |
7 | USB_DP | USB Serial | External SIM | SIM_VCC | 8 |
9 | USB_DN | USB Serial | External SIM | SIM_RST | 10 |
11 | GND | Power | External SIM | SIM_IO | 12 |
13 | VUSB | USB Serial | External SIM | SIM_CLK | 14 |
15 | NC | External SIM | SIM_NPRESENT | 16 | |
17 | NC | Power | GND | 18 | |
19 | NC | Active GPS | VACT_GPS_OUT | 20 | |
21 | NC | Active GPS | VACT_GPS_IN | 22 | |
23 | NC | MODULE KEY | -- | 24 | |
25 | -- | MODULE KEY | MODULE KEY | -- | 26 |
27 | -- | MODULE KEY | MODULE KEY | -- | 28 |
29 | -- | MODULE KEY | MODULE KEY | -- | 30 |
31 | -- | MODULE KEY | NC | 32 | |
33 | GND | Power | NC | 34 | |
35 | NC | NC | 36 | ||
37 | NC | Auxiliary Ports | AUX5 | 38 | |
39 | GND | Power | I2C Serial | SCL_P | 40 |
41 | NC | I2C Serial | SDA_P | 42 | |
43 | NC | NC | 44 | ||
45 | GND | Power | Auxiliary Ports | AUX1 | 46 |
47 | NC | Auxiliary Ports | AUX2 | 48 | |
49 | NC | Auxiliary Ports | AUX3 | 50 | |
51 | GND | Power | Auxiliary Ports | AUX4 | 52 |
53 | NC | Attention | ATTN_P | 54 | |
55 | NC | Auxiliary Ports | AUX_EN_P | 56 | |
57 | GND | Power | Auxiliary Ports | AUX_RX_P | 58 |
59 | NC | Auxiliary Ports | AUX_TX_P | 60 | |
61 | NC | UART Serial | RX_P | 62 | |
63 | NC | UART Serial | TX_P | 64 | |
65 | NC | NC | 66 | ||
67 | NRST | Reset | NC | 68 | |
69 | NC | Power | VMODEM_P | 70 | |
71 | GND | Power | Power | VMODEM_P | 72 |
73 | GND | Power | Power | VMODEM_P | 74 |
75 | NC |
Link: Digi-Key part number of the connector - Both Digi-Key and Mouser have pictures for this part number that show a component with a different key, but both have links to datasheet/drawing/CAD models.
All pins whose Functional Interface is marked "Power" must be connected.
All pins named NC
MUST have no connection and be left open because they are
reserved for future use. Furthermore, any pin not used in a design MUST also be
left open.
Those pins ending with _P
may be optionally protected from anomalous external
conditions on some Notecarrier designs, depending upon use-case specific
requirements.
Technical Details
Host Microcontroller API
Notecard supports a rich, simple API whose syntax is standard JSON. The
developer can communicate requests to Notecard, generally by using little more
than printf
functions available in most programming languages.
Serial Communication
JSON requests and responses (the Notecard's Application Programming Interface "API") may be sent over any of the following interfaces:
- USB Serial Interface
- UART Serial Interface
- I2C Interface
If NOT using a Notecard firmware library, you may unintentionally send requests to the Notecard so fast that you overflow the 1500 byte buffer used to receive data (whether it be I2C, Serial, or UART). The solution is to pause 250 ms after every 250 bytes sent and ensure the total size of each NDJSON object sent is no more than 8KB.
API Reference
For API usage, names, and parameters, please refer to the Notecard API Reference.
USB Serial Interface
The USB Serial Interface appears to the host as a USB 2.0 Full Speed CDC device. You can access it from Linux, Windows, or macOS without a device driver using terminal emulation software. Newline-delimited JSON requests may be sent directly as UTF-8 text over this port, or you may use the open-source Blues libraries for C, Python, Go, and Arduino.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
USB_DM | I/O | 9 | USB D- data signal |
USB_DP | I/O | 7 | USB D+ data signal |
VUSB | IN | 13 | +5V from USB |
GND | I/O | 11 | Ground from USB |
UART Serial Interface
The UART Serial Interface operates at VIO_P
at a fixed baud rate of 9600 using
eight data bits, no parity bit, and one stop bit. Newline-delimited JSON
requests may be sent directly as UTF-8 text over this port, or you may use the
open-source Blues libraries for C, Python, Go, and Arduino.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
RX_P | IN | 62 | Receive data signal |
TX_P | OUT | 64 | Transmit data signal |
I2C Interface
The Notecard acts as an I2C secondary device operating at VIO_P
, and it
implements a simple
Serial-over-I2C protocol.
You can access it from an embedded host using open-source Blues
libraries for C, Python, Go, and Arduino.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
SCL_P | IN | 40 | I2C clock |
SDA_P | I/O | 42 | I2C data |
Host Microcontroller Hardware Interface
Attention Interrupt
Using software, you can optionally configure Notecard to use the ATTN
output
pin to:
- Inform the host MCU of certain asynchronous events (such as incoming data availability, or Notecard motion) in an interrupt-driven manner rather than just polling.
- Place the host MCU into a power-off sleep state and wake it back up again.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
ATTN_P | OUT | 54 | Attention pin |
This pin operates at VIO_P
. If it is unused it can be left disconnected.
Auxiliary Ports
An optional Auxiliary UART Serial Interface is available on the AUX_RX_P
and
AUX_TX_P
pins. This interface is inactive unless enabled by raising the
AUX_EN_P
pin since this UART consumes extra power when in use. It operates at
VIO_P
at a fixed baud rate of 115200 using eight data bits, no parity bit, and
one stop bit. If this interface is unused, the three pins can be left
disconnected.
The AUX1-4 pins operate at VIO_P
and can be configured in software to operate
in several optional modes such as GPS Tracking Mode, GPIO Mode, and Internet
Button Mode. If these pins are unused, they can be left disconnected.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
AUX_EN_P | IN | 56 | Enables serial port on AUX_RX_P and AUX_TX_P |
AUX_RX_P | IN | 58 | RX data for serial port enabled by AUX_EN_P |
AUX_TX_P | OUT | 60 | TX data for serial port enabled by AUX_EN_P |
AUX1 | I/O | 46 | General Purpose IO |
AUX2 | I/O | 48 | General Purpose IO |
AUX3 | I/O | 50 | General Purpose IO |
AUX4 | I/O | 52 | General Purpose IO |
AUX5 | I/O | 38 | Alt. attention pin or charge detection |
The auxiliary serial port is normally disabled because it consumes up to 100µA of power when enabled.
External SIM
Notecard contains an integrated, embedded MFF2 SIM but may also be configured to use an external 1.8V Micro-SIM via this interface. This interface is powered by the Notecard. Note that use of an external SIM card also requires that the Notecard be re-configured in software with the APN, access technology, and bands appropriate for the SIM's carrier.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
SIM_CLK | OUT | 14 | Clock |
SIM_IO | I/O | 12 | Data |
SIM_NPRESENT | IN | 16 | Active-low input indicating presence of SIM card, else must be NC . Required if an external SIM is used, and is supported by the mechanical switch in SIM card slot hardware. |
SIM_RST | OUT | 10 | Reset |
SIM_VCC | OUT | 8 | +1.8V supply for external Micro-SIM |
Reset
Use of this pin is optional. If the host system has a global reset line, caution should be used when connecting this pin to the host system's reset because the Notecard may independently pull the line low in software. Restrictions on this pin are:
- If this pin is not used, it must remain not connected (
NC
). - The pin is active-low. It must be held low for at least 350nS for a clean reset.
- This pin must never be pulled-up. A pull-up would interfere with the Notecard's own internal watchdog timer and thus will prevent reliable operations.
- Some Notecarriers may invert this signal to be active-high.
Pin Name | Direction | Pin Number | Usage |
---|---|---|---|
NRST | I/O | 67 | Active-low reset |
Network Communication Behavior
The Notecard includes a built-in connection to Notehub.io
(specifically a.notefile.net:8086
) and communicates over SSL. Outbound
connections speak directly with the Notehub session load balancer
(or "Discovery Service") for provisioning and device authentication. By default,
the TLS connection is unidirectional, but can operate bi-directionally,
if needed. The keys and certificates for each device are provisioned by
STMicrosystems inside the STSAFE secure element present on every Notecard.
Once the Discovery Service has provisioned or authenticated a device, it issues
a "ticket" and a Handler IP address that the Notecard can use to make subsequent
requests.
The Notecard can also connect to the Handler to do a constrained set of
remote procedure calls related to synchronization. If the Notecard determines
that the data queued for transmission to or from the Handler should be
encrypted, it opens a session to the Handler on port 8086
. Otherwise,
an unencrypted socket is opened on port 8081
.
The over-the-wire data transmitted on both sockets is highly byte-optimized, which is why raw SSL and TCP sockets are used, and not unoptimized HTTP/HTTPS transactions.
Specifications
General Characteristics
Description | Value |
---|---|
Weight | 6 grams |
Electrical Characteristics
Absolute Maximum Ratings
Description | Minimum | Maximum | Unit |
---|---|---|---|
Storage temperature | -40 | 80 | °C |
Ambient operating temperature | -35 | 75 | °C |
DC Characteristics
Description | Minimum | Maximum | Unit |
---|---|---|---|
Supply Voltage | 2.5 | 5.5 | V |
Ordering Information
Certifications
FCC
FCC certification indicates that a product complies with the regulations set forth by the Federal Communications Commission (FCC) in the United States. This certification ensures that electronic devices do not emit electromagnetic interference that could disrupt other electronic devices and communication systems.
Download the NOTE-WBNA FCC/ICES Test Report
Certification | Date |
---|---|
FCC: 47 CFR FCC Part 15, Subpart B, Class B | November 2021 |
FCC: ICES-003:2016 Issue 6, Class B | November 2021 |
FCC: ANSI C63.4:2014 | November 2021 |
PTCRB
PTCRB certification is a certification process for mobile and cellular devices that ensures they meet the necessary standards and specifications for operation on North American cellular networks. PTCRB (PCS Type Certification Review Board) was established by North American cellular operators to define test specifications and methods to ensure device interoperability.
Download the NOTE-WBNA PTCRB Test Report
Property | Value |
---|---|
Model Name/Number | NOTE-WBNA |
Technologies/Bands | UMTS FDD: Band II/Band IV/Band V E-UTRA FDD: Band 2/Band 4/Band 5/Band 12/Band 13/Band 25/Band 26 |
E-UTRA CA Bands Supported | No |
FCC ID | XMR201909EG91NAX |
Industry Canada (IC) # | 10224A-021EG91NAXD |
IMEI TAC | 86805004 |
Hardware Version | 1.5.0 |
Software Version | 1.5.0 |
SVN | 03 |
NAPRD.03 Version | 5.41 LwM2M Test/AT Commands Test/GNSS Test/E-UTRA Test/UMTS FDD Test/SISO OTA Performance Test/Connection Efficiency Test |
Module Manufacturer | Quectel |
Module Model Number | EG91-NAX |
Module Hardware Version | R1.0 |
Module Software Version | EG91NAXGAR07A03M1G |
Other PTCRB Certifications | Date |
---|---|
PTCRB "socket modem" certification as an "End-Product" | February 2019 |
Other
Certification | Date |
---|---|
3GPP TS 36.124 | November 2021 |
RoHS | December 2021 |
Terms and Conditions
Visit Blues Hardware Terms & Conditions
Security and Vulnerability Scanning
As a part of our regular audit and scanning process, Blues Inc. performs full vulnerability scanning every six months. Any identified vulnerabilities will be analyzed, reported, and patched in a timely fashion, where appropriate.
Revision History
Author | Date | Summary |
---|---|---|
Ray Ozzie | 2019-2020 | Document drafted |
John Wiedey | 2020 | Various improvements |
Sean Taylor | 2020 | Various improvements |
Zachary J. Fields | 11 SEP 2020 | Updated information and translated to markdown |
Brandon Satrom | 13 APR 2021 | Updated Country list based on carrier audit |
Carlton Henderson | 12 JUL 2021 | Update coverage information |
Carlton Henderson | 12 JUL 2021 | Fix block diagram photo |
Brandon Satrom | 11 NOV 2021 | Added Certification Dates |
Brandon Satrom | 07 JAN 2022 | Added RoHS Certification Dates |
Brandon Satrom | 15 FEB 2022 | Add Wi-Fi Notecard Datasheet |
Rob Lauer | 25 AUG 2022 | Added updated certification data |
Rob Lauer | 27 OCT 2022 | Update country coverage information |
Rob Lauer | 13 JAN 2023 | Added RF performance information |
Rob Lauer | 2 FEB 2023 | Warning re: STM32 light sensitivity |
Kimball Johnson | 21 SEP 2023 | Updated for new Cellular + Wi-Fi, LoRa, and Wi-Fi Notecards |
Rob Lauer | 23 OCT 2023 | Update and clarify power consumption values |
Rob Lauer | 31 JAN 2023 | Update Notecard for LoRa datasheet details |
Rob Lauer | 16 APR 2024 | Updated for new Cellular (black PCB) Notecards, MB Cellular Notecards, and Notecard XP |
Rob Lauer | 6 JUN 2024 | Added cell band support for Cellular Notecards |
Rob Lauer | 23 JUL 2024 | Update pin definitions |
TJ VanToll | 24 SEP 2024 | Adding Notecard for LoRa v2.1 information |
Contact Information
Blues Inc.
https://blues.com
50 Dunham Ridge Suite 1650
Beverly, MA 01915
support@blues.com