Arduino Nano 33 ble rev2 User manual

Arduino® Nano 33 BLE Rev2

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Product Reference Manual

SKU: ABX00071

Description

The Arduino Nano 33 BLE Rev2* is a miniature-sized module containing a NINA B306 module, based on Nordic

nRF52480 and containing an Arm® Cortex®-M4F. The BMI270 and BMM150 jointly provide a 9-axis IMU. The

module can either be mounted as a DIP component (when mounting pin headers) or as a SMT component, directly

soldering it via the castellated pads.

*Nano 33 BLE Rev2 product has two SKUs:

Without headers (ABX00071)

With headers (ABX00072)

Target Areas

Maker, enhancements, IoT application

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Features

NINA B306 Module

Processor

64 MHz Arm® Cortex®-M4F (with FPU)

1 MB Flash + 256 KB RAM

Bluetooth® 5 multiprotocol radio

2 Mbps

CSA #2

Advertising Extensions

Long Range

+8 dBm TX power

-95 dBm sensitivity

4.8 mA in TX (0 dBm)

4.6 mA in RX (1 Mbps)

Integrated balun with 50 Ω single-ended output

IEEE 802.15.4 radio support

Thread

Zigbee

Peripherals

Full-speed 12 Mbps USB

NFC-A tag

Arm® CryptoCell CC310 security subsystem

QSPI/SPI/TWI/I²S/PDM/QDEC

High speed 32 MHz SPI

Quad SPI interface 32 MHz

EasyDMA for all digital interfaces

12-bit 200 ksps ADC

128 bit AES/ECB/CCM/AAR co-processor

BMI270 6-axis IMU (Accelerometer and Gyroscope)

16-bit

3-axis accelerometer with ±2g/±4g/±8g/±16g range

3-axis gyroscope with ±125dps/±250dps/±500dps/±1000dps/±2000dps range

BMM150 3-axis IMU (Magnetometer)

3-axis digital geomagnetic sensor

0.3μT resolution

±1300μT (x,y-axis), ±2500μT (z-axis)

MP2322 DC-DC

Regulates input voltage from up to 21V with a minimum of 65% eﬃciency @minimum load

More than 85% eﬃciency @12V

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Contents
1 The Board
1.1 Ratings
1.1.1 Recommended Operating Conditions
1.2 Power Consumption
2 Functional Overview
2.1 Board Topology
2.2 Processor
2.3 IMU
2.4 Power Tree
2.5 Block Diagram
3 Board Operation
3.1 Getting Started - IDE
3.2 Getting Started - Arduino Web Editor
3.3 Getting Started - Arduino IoT Cloud
3.4 Sample Sketches
3.5 Online Resources
3.6 Board Recovery
4 Connector Pinouts
4.1 USB
4.2 Headers
4.3 Debug
5 Mechanical Information
5.1 Board Outline and Mounting Holes
6 Certiﬁcations
6.1 Declaration of Conformity CE DoC (EU)
6.2 Declaration of Conformity to EU RoHS & REACH 211 01/19/2021
6.3 Conﬂict Minerals Declaration
7 FCC Caution
8 Company Information
9 Reference Documentation
10 Revision History

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1 The Board

As all Nano form factor boards, Nano 33 BLE Rev2 does not have a battery charger but can be powered through

USB or headers.

NOTE: Nano 33 BLE Rev2 only supports 3.3 V I/Os and is NOT 5V tolerant so please make sure you are not directly

connecting 5 V signals to this board or it will be damaged. Also, as opposed to other Arduino Nano boards that

support 5 V operation, the 5V pin does NOT supply voltage but is rather connected, through a jumper, to the USB

power input.

1.1 Ratings

1.1.1 Recommended Operating Conditions

Symbol Description Min Max

Conservative thermal limits for the whole board: -40 °C ( 40 °F) 85 °C ( 185 °F)

1.2 Power Consumption

Symbol Description Min Typ Max Unit

PBL Power consumption with busy loop TBC mW

PLP Power consumption in low power mode TBC mW

PMAX Maximum Power Consumption TBC mW

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2 Functional Overview

2.1 Board Topology

Top:

Board topology top

Ref. Description Ref. Description

U1 NINA-B306 Module Bluetooth® Low Energy 5.0 Module U6 MP2322GQH Step Down Converter

U2 BMI270 Sensor IMU PB1 IT-1185AP1C-160G-GTR Push button

U7 BMM150 Magnetometer IC DL1 Led L

SJ5 VUSB Jumper

Bottom:

Board topology bot

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Ref. Description Ref. Description

SJ1 VUSB Jumper SJ2 D7 Jumper

SJ3 3v3 Jumper SJ4 D8 Jumper

2.2 Processor

The Main Processor is an Arm® Cortex®-M4F running at up to 64 MHz. Most of its pins are connected to the

external headers however some are reserved for internal communication with the wireless module and the on-

board internal I2C peripherals (IMU and Crypto).

NOTE: As opposed to other Arduino Nano boards, pins A4 and A5 have an internal pull-up and default to be used as

an I2C Bus so usage as analog inputs is not recommended.

2.3 IMU

Nano 33 BLE Rev2 provides IMU capabilities with 9-axis, through a combination of the BMI270 and BMM150 ICs.

The BMI270 includes both a three-axis gyroscope as well as a three-axis accelerometer, while the BMM150 is

capable of sensing magnetic ﬁeld variations in all three dimensions. The information obtained can be used for

measuring raw movement parameters as well as for machine learning.

2.4 Power Tree

The board can be powered via USB connector, VIN or VUSB pins on headers.

Power tree

NOTE: Since VUSB feeds VIN via a Schottky diode and a DC-DC regulator speciﬁed minimum input voltage is 4.5 V the

minimum supply voltage from USB has to be increased to a voltage in the range between 4.8 V to 4.96 V depending

on the current being drawn.

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2.5 Block Diagram

Block Diagram

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3 Board Operation

3.1 Getting Started - IDE

If you want to program your Nano 33 BLE Rev2 while oﬄine you need to install the Arduino Desktop IDE [1] To

connect the Nano 33 BLE Rev2 to your computer, you’ll need a Micro-B USB cable. This also provides power to the

board, as indicated by the LED.

3.2 Getting Started - Arduino Web Editor

All Arduino boards, including this one, work out-of-the-box on the Arduino Web Editor, by just installing a simple

plugin.

The Arduino Web Editor is hosted online, therefore it will always be up-to-date with the latest features and support

for all boards. Follow to start coding on the browser and upload your sketches onto your board.

3.3 Getting Started - Arduino IoT Cloud

All Arduino IoT-enabled products are supported on Arduino IoT Cloud which allows you to log, graph and analyze

sensor data, trigger events, and automate your home or business.

3.4 Sample Sketches

Sample sketches for the Nano 33 BLE Rev2 can be found either in the “Examples” menu in the Arduino IDE or in the

“Built-in Examples” section of the Arduino Docs website.

3.5 Online Resources

Now that you have gone through the basics of what you can do with the board you can explore the endless

possibilities it provides by checking exciting projects on ProjectHub, the Arduino Library Reference and the online

store where you will be able to complement your board with sensors, actuators and more.

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3.6 Board Recovery

All Arduino boards have a built-in bootloader which allows ﬂashing the board via USB. In case a sketch locks up the

processor and the board is not reachable anymore via USB it is possible to enter bootloader mode by double-

tapping the reset button right after powering up the board.

4 Connector Pinouts

Pinout

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4.1 USB

Pin Function Type Description

1 VUSB Power Power Supply Input. If board is powered via VUSB from header this is an Output (1)

2 D- Diﬀerential USB diﬀerential data -

3 D+ Diﬀerential USB diﬀerential data +

4 ID Analog Selects Host/Device functionality

5 GND Power Power Ground

4.2 Headers

The board exposes two 15-pin connectors which can either be assembled with pin headers or soldered through

castellated vias.

Pin Function Type Description

1 D13 Digital GPIO

2 +3V3 Power Out Internally generated power output to external devices

3 AREF Analog Analog Reference; can be used as GPIO

4 A0/DAC0 Analog ADC in/DAC out; can be used as GPIO

5 A1 Analog ADC in; can be used as GPIO

6 A2 Analog ADC in; can be used as GPIO

7 A3 Analog ADC in; can be used as GPIO

8 A4/SDA Analog ADC in; I2C SDA; Can be used as GPIO (1)

9 A5/SCL Analog ADC in; I2C SCL; Can be used as GPIO (1)

10 A6 Analog ADC in; can be used as GPIO

11 A7 Analog ADC in; can be used as GPIO

12 VUSB Power

In/Out

Normally NC; can be connected to VUSB pin of the USB connector by shorting a

jumper

13 RST Digital In Active low reset input (duplicate of pin 18)

14 GND Power Power Ground

15 VIN Power In Vin Power input

16 TX Digital USART TX; can be used as GPIO

17 RX Digital USART RX; can be used as GPIO

18 RST Digital Active low reset input (duplicate of pin 13)

19 GND Power Power Ground

20 D2 Digital GPIO

21 D3/PWM Digital GPIO; can be used as PWM

22 D4 Digital GPIO

23 D5/PWM Digital GPIO; can be used as PWM

24 D6/PWM Digital GPIO, can be used as PWM

25 D7 Digital GPIO

26 D8 Digital GPIO

27 D9/PWM Digital GPIO; can be used as PWM

28 D10/PWM Digital GPIO; can be used as PWM

29 D11/MOSI Digital SPI MOSI; can be used as GPIO

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Pin Function Type Description

30 D12/MISO Digital SPI MISO; can be used as GPIO

4.3 Debug

On the bottom side of the board, under the communication module, debug signals are arranged as 3x2 test pads

with 100 mil pitch with pin 4 removed. Pin 1 is depicted in Figure 3 – Connector Positions

Pin Function Type Description

1 +3V3 Power Out Internally generated power output to be used as voltage reference

2 SWD Digital nRF52480 Single Wire Debug Data

3 SWCLK Digital In nRF52480 Single Wire Debug Clock

5 GND Power Power Ground

6 RST Digital In Active low reset input

5 Mechanical Information

5.1 Board Outline and Mounting Holes

The board measures are mixed between metric and imperial. Imperial measures are used to maintain a 100 mil

pitch grid between pin rows to allow them to ﬁt a breadboard whereas board length is Metric.

Board layout

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6 Certifications

6.1 Declaration of Conformity CE DoC (EU)

We declare under our sole responsibility that the products above conform with the essential requirements of the

following EU Directives and therefore qualify for free movement within markets comprising the European Union

(EU) and European Economic Area (EEA).

6.2 Declaration of Conformity to EU RoHS & REACH 211 01/19/2021

Arduino boards are in compliance with RoHS 2 Directive 2011/65/EU of the European Parliament and RoHS 3

Directive 2015/863/EU of the Council of 4 June 2015 on the restriction of the use of certain hazardous substances in

electrical and electronic equipment.

Substance Maximum limit (ppm)

Lead (Pb) 1000

Cadmium (Cd) 100

Mercury (Hg) 1000

Hexavalent Chromium (Cr6+) 1000

Poly Brominated Biphenyls (PBB) 1000

Poly Brominated Diphenyl ethers (PBDE) 1000

Bis(2-Ethylhexyl} phthalate (DEHP) 1000

Benzyl butyl phthalate (BBP) 1000

Dibutyl phthalate (DBP) 1000

Diisobutyl phthalate (DIBP) 1000

Exemptions: No exemptions are claimed.

Arduino boards are fully compliant with the related requirements of European Union Regulation (EC) 1907 /2006

concerning the Registration, Evaluation, Authorization and Restriction of Chemicals (REACH). We declare none of the

SVHCs (https://echa.europa.eu/web/guest/candidate-list-table), the Candidate List of Substances of Very High

Concern for authorization currently released by ECHA, is present in all products (and also package) in quantities

totaling in a concentration equal or above 0.1%. To the best of our knowledge, we also declare that our products do

not contain any of the substances listed on the "Authorization List" (Annex XIV of the REACH regulations) and

Substances of Very High Concern (SVHC) in any signiﬁcant amounts as speciﬁed by the Annex XVII of Candidate list

published by ECHA (European Chemical Agency) 1907 /2006/EC.

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6.3 Conflict Minerals Declaration

As a global supplier of electronic and electrical components, Arduino is aware of our obligations with regard to laws

and regulations regarding Conﬂict Minerals, speciﬁcally the Dodd-Frank Wall Street Reform and Consumer

Protection Act, Section 1502. Arduino does not directly source or process conﬂict minerals such as Tin, Tantalum,

Tungsten, or Gold. Conﬂict minerals are contained in our products in the form of solder or as a component in metal

alloys. As part of our reasonable due diligence, Arduino has contacted component suppliers within our supply chain

to verify their continued compliance with the regulations. Based on the information received thus far we declare

that our products contain Conﬂict Minerals sourced from conﬂict-free areas.

7 FCC Caution

Any Changes or modiﬁcations not expressly approved by the party responsible for compliance could void the user’s

authority to operate the equipment.

This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions:

(1) This device may not cause harmful interference

(2) this device must accept any interference received, including interference that may cause undesired operation.

FCC RF Radiation Exposure Statement:

1. This Transmitter must not be co-located or operating in conjunction with any other antenna or transmitter.

2. This equipment complies with RF radiation exposure limits set forth for an uncontrolled environment.

3. This equipment should be installed and operated with a minimum distance of 20cm between the radiator &

your body.

English: User manuals for license-exempt radio apparatus shall contain the following or equivalent notice in a

conspicuous location in the user manual, alternatively on the device or both. This device complies with Industry

Canada license-exempt RSS standard(s). Operation is subject to the following two conditions:

(1) this device may not cause interference

(2) this device must accept any interference, including interference that may cause undesired operation of the

device.

French: Le présent appareil est conforme aux CNR d’Industrie Canada applicables aux appareils radio exempts de

licence. L’exploitation est autorisée aux deux conditions suivantes :

(1) l’ appareil nedoit pas produire de brouillage

(2) l’utilisateur de l’appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible

d’en compromettre le fonctionnement.

IC SAR Warning:

English This equipment should be installed and operated with a minimum distance of 20 cm between the radiator

and your body.

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French: Lors de l’ installation et de l’ exploitation de ce dispositif, la distance entre le radiateur et le corps est d ’au

moins 20 cm.

Important: The operating temperature of the EUT can’t exceed 85℃ and shouldn’t be lower than -40℃.

Hereby, Arduino S.r.l. declares that this product complies with essential requirements and other relevant provisions

of Directive 2014/53/EU. This product is allowed to be used in all EU member states.

Frequency bands Maximum output power (ERP)

863-870Mhz TBD

8 Company Information

Company name Arduino S.r.l

Company Address Via Andrea Appiani 25 20900 MONZA Italy

9 Reference Documentation

| Reference | Link | | ------------------------- | ----------------------------------------------------------------------------------------------------- | -

https://create.arduino.cc/editor | | Cloud IDE Getting Started |

https://create.arduino.cc/projecthub/Arduino_Genuino/getting-started-with-arduino-web-editor-4b3e4a | | Forum

| http://forum.arduino.cc/ | | Nina B306 | https://content.u-blox.com/sites/default/ﬁles/NINA-B3_DataSheet_UBX-

Library Reference | https://www.arduino.cc/reference/en/ |

10 Revision History

Date Changes

2024/02/21 First Release

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