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    Released on Arduino Day 2018,Arduino MKR Wifi 1010 board provides low-power energy consumption and simplifies prototyping of WiFi based IoT applications.  It features a Microchip AT SAMD21, 48 Mhz 32 bit MO+ ARM Cortex low power processor. Its the same SAMD21 as the MKR 1000, MKR Zero, and Arduino/Genuino Zero boards.

     

    {gallery} My Gallery Title

     

     

    Arduino MKR WiFi 1010:

     

    Product NameQuantity
    Arduino MKR WiFi 1010 Development Board1Buy NowBuy Now

     

     

    Arduino MKR Shields:

     

    Product NameQuantity

    Arduino MKR SD Proto Shield

    1Buy NowBuy Now

    Arduino MKR CAN Shield

    1Buy NowBuy Now

    Arduino MKR Relay Proto Shield

    1Buy NowBuy Now

    Arduino MKR Connector Carrier

    1Buy NowBuy Now

    Arduino MKR MEM Shield

    1Buy NowBuy Now

    Arduino MKR 485 Shield

    1Buy NowBuy Now
    Arduino MKR ETH Shield1Buy NowBuy Now
    Arduino MKR Proto Shield1Buy NowBuy Now
    Arduino MKR Proto Large Shield1Buy NowBuy Now

     

     

    The Arduino MKR 1010 uses the same pin mapping as the MRK 1000:

     

             

     

     

    Power Pins:

    • Li-Po (3.7V) - You can power the board by connecting a Lithium polymer battery (shown to the right) with a nominal voltage of 3.7.
    • Vin - The board can be powered by a regulated 5V supply with a maximum voltage of 6V for this Pin.
    • 5V - When the board is powered by USB, you can use this pin get +5V to power other circuit
    • Vcc - This pin uses the on board regulator IC to output a regulated 3.3V
    • GND - Ground Pins

     

    Reset Pin - Bring this line LOW to reset the microcontroller. Typically used to add a reset button to shields which block the one on the board.

     

    Analog Pins (Pins A0-A06) - The 7 analog pins are used to emasure analog voltage in the range 0- 3.3V with a resolution of 10 bit.

     

    DAC0 Pin - The DAC pin is just above the Analog Pins and is used provide an analog voltage based in the digital input with a resolution of 10bit.

     

    Digital I/O Pins (Pins 0-14) - Below the analog pins on the left and just below the reset are digital pins that can be used as either input or output pins.  Low is at 0V and high is at 3.3V.

     

    Serial Rx, Tx Pins (Pins 13, 14) - Pins 13 and 14 are used to Receive (Rx) and Transmit (Tx) TTL serial data. These pins are connected to the corresponding pins of the FTDI USB-to-TTL serial chip.

     

    External Interrupts (Pins 0,1, 4, 5,6, 7, 8, A1, A4) - These pins can be used to trigger an interrupt on a low value, a rising or falling edge, or a change in value. See attachInterrupt()function for details.

     

    PWM Pins (Pins 0, 1, 2, 3, 4, 5, 6, 7, 8, 10, A3, A4) - These pins provide 8-bit PWM output with the analogWrite () function.

     

    SPI (Pin 8 - MOSI, Pin 9 - SCK, Pin 10 - MISO) -  These pins support SPI Communication

     

    LED - There is a built-in LED connected to digital pin 13. When the pin is HIGH value, the LED is on, when the pin is LOW, it's off.

     

    I2C Pins (Pin 11 is SDA and Pin 12 is SCL) -  Pin 11 (SDA) and Pin 12(SCL)  support I2C (TWI) communication using the Wire library (documentation on the Wiring website).

     

    AREF Pin - Reference voltage for the analog inputs. Used with analogReference().

     

     

    The low power, high performance ARM Cortex-MO+ is ideal for a wide range of home automation, consumer, metering, and industrial applications. Its the same SAMD21 as the MKR 1000, MKR Zero, and Arduino/Genuino Zero boards. A unique feature of the SAMD21 chip is SERCOM, a set of six configurable serial interfaces.  These can be turned into either a UART, I2C master, I2C slave, SPI master, and SPI slave. Additionally it features a 32-bit Real-Time Clock and calendar, 20 PWM channels, one 14-channel 12-bit ADC, on 10-bit DAC.

     

     

     

    ATSAMD21G18A Overview
    ArchitectureARM Cortex-MO+
    Voltage Range1.62-3.63V
    Bus Size32-Bit
    Max CPU Speed48MHz
    Internal Oscillator21khz, 23Khz ULP, 8Mhz
    Program Memory Size256KB
    SRAM32KB
    EEPROM32KB (emulated from Flash)
    GPIO38
    ADC Channels14
    ADC Resolution12-bit
    Digital-to-Analog Converter (DAC)Yes
    USB ControllerYes
    Direct Memory Access (DMA)12 Channel
    Peripheral Touch ControllerYes
    Inter-IC Sound 12SYes

     

    32 bits, 48 Mhz

     

    The 32 bit architecture allows you to process your instructions faster at double the speed of an 8-bit AVR. While the AVR must process data in 8-bit, the 32-bit architecture allows the SAMD21G to process data in one large chunk.

     

    Memory Map:

     

     

    USB Controller

     

    Like the ATmega32U4 used on the Leonardo, ATSAMD21 comes with an integrated USB controller, allowing it to be used as either a USB device or host. In device mode it configures itself as a USB CDC (communication device class) so that your computer talks to it as if it were a serial port. This allows the SAMD21 to emulate a mouse, keyboard, or controller, and also work as a mass flash storage.  If used as a USB host it can connect to keyboard or mouse, as well as, save data to a USB flash drive.  However, to act as a host requires extra power supply.

     

    Real-Time Clock

     

    The SAMD21 has a separate real time clock (RTC), powered by an on board 32.78 crystal, that runs at a full 48 MHz.  Also, almost every pin is tied to timer-counter, giving you a lot more PWM-capable I/O pins so you'll have plenty of options for dimming lights or controlling motors.

     

    ESP32 Module by u-blox

     

    The MKR WiFi 1010 adds an ESP32 module by u-blox which is a notable improvement from the MKR1000 Wifi. The NINA-W102 Module provides low power 2.4 Ghz 802.11 b/g/n WiFi, dual-mode bluetooth v. 4.2, and RF communication through an internal PIFA antenna.  This multiradio MCU integrates a powerful MCU with and a radio for wireless communication. Its open CPU architecture supports advanced applications on a 32-bit mcu. Radio is supported for 802.11 b/g/n WiFi in the 2.4 Ghz band, Bluetooth BR/EDR, and Bluetooth low energy.  The ESP32-W10 module has applications for automotive, smart cities, autonomous vehicles, medical technology, home and building automation.

     

     

    Block Diagram:

     

     

     

    WiFiBluetooth BR/EDRBluetooth Low Energy
    IEE 802.11b/g/n

    Bluetooth v4.2+ EDR

    Max. number of slaves: 7

    Bluetooth 4.2 BLE dual-mode

    Band support

    2.4 GHz, channel 1-13*

    Band support

    2.3 GHz, 79 channels

    Band support

    2.4 GHz, 40 channels

    Maximum conducted output power

    16 dBm

    Maximum conducted output power

    5 dBm

    Maximum conducted output power

    5 dBm

    Maximum radiated output power

    19 EIRP**

    Maximum radiated output power

    8 dBm EIRP**

    Maximum radiated output power

    8 dBm EIRP**

    Conducted Sensitivity

    -96 dBm

    Conducted Sensitivity

    -90 dBm

    Conductivity

    -90 dBM

    Data Rates:

    IEEE 802.11b:

      1/2/5.5/11 Mbit/s

    IEEE 802.11g:

      6/9/12/18/24/36/48/54 Mbit/s

    IEEE 802.11n:

      MSC 0-7, HT20 (6.5-72 Mbit/s)

    Data Rates:

    1/2/3 Mbit/s

    Data Rates

      1 Mbit/s

     

    * Depending on location (country, region) channels 12-13 must be disabled and support the country determination algorithm for supporting

     

    **RF antenna including maximum antenna gain (3 dBi)

     

    EEC502

     

    Another key feature of the MKR WiFi 1010 is that it has an integrated Cryptochip, Microchip ECC508, for secure communication using SHA 256 encryption.

     

    Reference links:

     

     

    Github links:

     

    Enables network connection (local and Internet) with the Arduino MKR WiFi 1010, Arduino MKR VIDOR 4000 and Arduino UNO WiFi Rev.2: https://github.com/arduino-libraries/WiFiNINA

    Source code and configuration files of the Arduino Core for Atmel's SAMD21 processor: https://github.com/arduino/ArduinoCore-samd

    API to communicate with LoRa and LoRaWAN networks: https://github.com/arduino-libraries/MKRWAN

    Arduino Command Line Interface: https://github.com/arduino/arduino-cli

     

    FAQ:

     

    What is the Arduino NINA-102 Firmware link for BLE support?

     

     

    Is possible to execute control algotithm and Machine learning based on data collected in the cloud?

     

    • Once we release our APIs you can for sure fetch the data and build ML algorithms on top of those. Also considering clever ways for opening real time streams.

     

    Any plans to enable OTA functionality on the MKR 1400 device?

     

    • Yes. the MKR1010 will have OTA soon. the MKR1000 require and external memory, GSM TOO