How to Setup and Change the System Clock on the SAMD21 Microcontroller Family

In this video we look at how to setup and change the system clock on the SAMD21 family of microcontrollers from Microchip / Atmel. This example code is written in C++ and uses direct register access.

Where to access the two versions of the code

• Free version can be found on GitHub: https://github.com/ForceTronics/SamD21_Clock_Setup

• For pay version includes the following additional features:

• Demonstrates how to use the calibration values stored in NVM to tune the 48MHz clock for higher accuracy

• Allows you to change the system clock to 48MHz, 8MHz, 1MHz, and 32768Hz

• Shows how to output the system clock from pin PA27

• Link to code on ForceTronics.com: http://www.forcetronics.com/example-code-for-purchase/samd21-clock-setup-and-control-c-code-example

Speeding up the ADC on Arduino SAMD21 Boards (Zero, Mkr, etc) Part 2

In this video we look at how to get higher ADC speeds out of Arduino boards that are based off of the SAMD21 microcontroller. In part 2 we discuss memory limitations and we leverage an Adafruit library to do an FFT on the ADC data.

Link to details on PCBWay Maker Contest: ttps://www.pcbway.com/project/PCB_DESIGN_CONTEST.aspx

//*******************Arduino Code from Video*********************************
/*This code is from a tutorial on the ForceTronics YouTube Channel that talks about speeding up the sample rate on Arduino boards 
 * that use the SAMD21 microcontroller like the Arduino Zero or MKR series. This code is free and clear for other to use and modify 
 * at their own risk. 
 */
#include "Adafruit_ZeroFFT.h" //adafruit library for FFT
#include <SPI.h>
#include <SD.h>

const long sRate = 300000; //sample rate of ADC
const int16_t dSize = 1024; //used to set number of samples
const byte chipSelect = 38; //used for SPI chip select pin
const byte gClk = 3; //used to define which generic clock we will use for ADC
const byte intPri = 0; //used to set interrupt priority for ADC
const int cDiv = 1; //divide factor for generic clock
const float period = 3.3334; //period of 300k sample rate
String wFile = "ADC_DATA"; //used as file name to store wind and GPS data
volatile int16_t aDCVal[dSize]; //array to hold ADC samples
volatile int count = 0; //tracks how many samples we have collected
bool done = false; //tracks when done writing data to SD card

void setup() {
  portSetup(); //setup the ports or pin to make ADC measurement
  genericClockSetup(gClk,cDiv); //setup generic clock and routed it to ADC
  aDCSetup(); //this function set up registers for ADC, input argument sets ADC reference
  setUpInterrupt(intPri); //sets up interrupt for ADC and argument assigns priority
  aDCSWTrigger(); //trigger ADC to start free run mode
}

void loop() {
  
  if(count==(dSize-1) and !done) { //if done reading and they have not been written to SD card yet
    removeDCOffset(aDCVal, dSize, 8); //this function removes DC offset if you are measuring an AC signal
    int16_t fTTVal[dSize]; //array to hold FFT samples
    for(int j=0; j<dSize; j++) fTTVal[j] = aDCVal[j]; //copy one array to another array
    ZeroFFT(fTTVal,dSize); //calculate FFT and store into array
    SD.begin(chipSelect); //start SD card library
    File myFile = SD.open((wFile + ".csv"), FILE_WRITE); //open file to write data to CSV file
    if (myFile) {
      float sTime = 0;
      for (int y = 0; y < dSize; y++) { //write each reading to CSV 
        myFile.print(String(FFT_BIN(y, sRate, dSize))+",");
        myFile.print(String((fTTVal[y]))+",");
        myFile.print(sTime,5); //write each reading to SD card as string
        myFile.print(",");
        myFile.println(String(aDCVal[y])+","); //write each reading to SD card as string
        sTime = sTime + period; //update signal period info
      }
    }
    myFile.close(); //close file
    done = true; //we are done 
  }
}

//function for configuring ports or pins, note that this will not use the same pin numbering scheme as Arduino
void portSetup() {
  // Input pin for ADC Arduino A0/PA02
  REG_PORT_DIRCLR1 = PORT_PA02;

  // Enable multiplexing on PA02_AIN0 PA03/ADC_VREFA
  PORT->Group[0].PINCFG[2].bit.PMUXEN = 1;
  PORT->Group[0].PINCFG[3].bit.PMUXEN = 1;
  PORT->Group[0].PMUX[1].reg = PORT_PMUX_PMUXE_B | PORT_PMUX_PMUXO_B;
}

//this function sets up the generic clock that will be used for the ADC unit
//by default it uses the 48M system clock, input arguments set divide factor for generic clock and choose which generic clock
//Note unless you understand how the clock system works use clock 3. clocks 5 and up can brick the microcontroller based on how Arduino configures things
void genericClockSetup(int clk, int dFactor) {
  // Enable the APBC clock for the ADC
  REG_PM_APBCMASK |= PM_APBCMASK_ADC;
  
  //This allows you to setup a div factor for the selected clock certain clocks allow certain division factors: Generic clock generators 3 - 8 8 division factor bits - DIV[7:0]
  GCLK->GENDIV.reg |= GCLK_GENDIV_ID(clk)| GCLK_GENDIV_DIV(dFactor);
  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);  

  //configure the generator of the generic clock with 48MHz clock
  GCLK->GENCTRL.reg |= GCLK_GENCTRL_GENEN | GCLK_GENCTRL_SRC_DFLL48M | GCLK_GENCTRL_ID(clk); // GCLK_GENCTRL_DIVSEL don't need this, it makes divide based on power of two
  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);
  
  //enable clock, set gen clock number, and ID to where the clock goes (30 is ADC)
  GCLK->CLKCTRL.reg |= GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN(clk) | GCLK_CLKCTRL_ID(30);
  while (GCLK->STATUS.bit.SYNCBUSY);
}

/*
ADC_CTRLB_PRESCALER_DIV4_Val    0x0u  
ADC_CTRLB_PRESCALER_DIV8_Val    0x1u   
ADC_CTRLB_PRESCALER_DIV16_Val   0x2u   
ADC_CTRLB_PRESCALER_DIV32_Val   0x3u   
ADC_CTRLB_PRESCALER_DIV64_Val   0x4u   
ADC_CTRLB_PRESCALER_DIV128_Val  0x5u   
ADC_CTRLB_PRESCALER_DIV256_Val  0x6u   
ADC_CTRLB_PRESCALER_DIV512_Val  0x7u   
--> 8 bit ADC measurement takes 5 clock cycles, 10 bit ADC measurement takes 6 clock cycles
--> Using 48MHz system clock with division factor of 1
--> Using ADC division factor of 32
--> Sample rate = 48M / (5 x 32) = 300 KSPS
This function sets up the ADC, including setting resolution and ADC sample rate
*/
void aDCSetup() {
  // Select reference
  REG_ADC_REFCTRL = ADC_REFCTRL_REFSEL_INTVCC1; //set vref for ADC to VCC

  // Average control 1 sample, no right-shift
  REG_ADC_AVGCTRL |= ADC_AVGCTRL_SAMPLENUM_1;

  // Sampling time, no extra sampling half clock-cycles
  REG_ADC_SAMPCTRL = ADC_SAMPCTRL_SAMPLEN(0);
  
  // Input control and input scan
  REG_ADC_INPUTCTRL |= ADC_INPUTCTRL_GAIN_1X | ADC_INPUTCTRL_MUXNEG_GND | ADC_INPUTCTRL_MUXPOS_PIN0;
  // Wait for synchronization
  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);

  ADC->CTRLB.reg |= ADC_CTRLB_RESSEL_8BIT | ADC_CTRLB_PRESCALER_DIV32 | ADC_CTRLB_FREERUN; //This is where you set the divide factor, note that the divide call has no effect until you change Arduino wire.c
  //Wait for synchronization
  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);

  ADC->WINCTRL.reg = ADC_WINCTRL_WINMODE_DISABLE; // Disable window monitor mode
  while(ADC->STATUS.bit.SYNCBUSY);

  ADC->EVCTRL.reg |= ADC_EVCTRL_STARTEI; //start ADC when event occurs
  while (ADC->STATUS.bit.SYNCBUSY);

  ADC->CTRLA.reg |= ADC_CTRLA_ENABLE; //set ADC to run in standby
  while (ADC->STATUS.bit.SYNCBUSY);
}

//This function sets up an ADC interrupt that is triggered 
//when an ADC value is out of range of the window
//input argument is priority of interrupt (0 is highest priority)
void setUpInterrupt(byte priority) {
  
  ADC->INTENSET.reg |= ADC_INTENSET_RESRDY; // enable ADC ready interrupt
  while (ADC->STATUS.bit.SYNCBUSY);

  NVIC_EnableIRQ(ADC_IRQn); // enable ADC interrupts
  NVIC_SetPriority(ADC_IRQn, priority); //set priority of the interrupt
}

//software trigger to start ADC in free run
//in future could use this to set various ADC triggers
void aDCSWTrigger() {
  ADC->SWTRIG.reg |= ADC_SWTRIG_START;
}

//This ISR is called each time ADC makes a reading
void ADC_Handler() {
    if(count<1023) {
      aDCVal[count] = REG_ADC_RESULT;
      count++;
    }
    ADC->INTFLAG.reg = ADC_INTENSET_RESRDY; //Need to reset interrupt
}

//This function takes out DC offset of AC signal, it assumes that the offset brings signal to zero volts
//input arguments: array with measured points and bits of measurement
void removeDCOffset(volatile int16_t aDC[], int aSize, int bits) {
  int aSteps = pow(2,bits)/2; //get number of levels in ADC measurement and cut it in half
  for(int i=0; i<aSize; i++) {
    aDC[i] = aDC[i] - aSteps; //take out offset
  }
}

Speeding up the ADC on Arduino SAMD21 Boards (Zero, Mkr, etc) P1

In this video we look at how to get higher ADC speeds out of Arduino boards that are based off of the SAMD21 microcontroller.

Windows file paths from video:

• files that define register data structures: C:\Users\yourname\AppData\Local\Arduino15\packages\arduino\hardware\samd\1.6.18\bootloaders\sofia\Bootloader_D21_Sofia_V2.1\src\ASF\sam0\utils\cmsis\samd21\include\component
• wire.c file path: C:\Users\yourname\AppData\Local\Arduino15\packages\arduino\hardware\samd\1.6.18\cores\arduino

//*******************Arduino example code from video*************************

/*This code is from a tutorial on the ForceTronics YouTube Channel that talks about speeding up the sample rate on Arduino boards 

 * that use the SAMD21 microcontroller like the Arduino Zero or MKR series. This code is free and clear for other to use and modify 

 * at their own risk. 

 */

#include <SPI.h>

#include <SD.h>

const int16_t dSize = 1024; //used to set number of samples

const byte chipSelect = 38; //used for SPI chip select pin

const byte gClk = 3; //used to define which generic clock we will use for ADC

const byte intPri = 0; //used to set interrupt priority for ADC

const int cDiv = 1; //divide factor for generic clock

const float period = 3.3334; //period of 300k sample rate

String wFile = "ADC_DATA"; //used as file name to store wind and GPS data

volatile int aDCVal[dSize]; //array to hold ADC samples

volatile int count = 0; //tracks how many samples we have collected

bool done = false; //tracks when done writing data to SD card

void setup() {

  portSetup(); //setup the ports or pin to make ADC measurement

  genericClockSetup(gClk,cDiv); //setup generic clock and routed it to ADC

  aDCSetup(); //this function set up registers for ADC, input argument sets ADC reference

  setUpInterrupt(intPri); //sets up interrupt for ADC and argument assigns priority

  aDCSWTrigger(); //trigger ADC to start free run mode

}

void loop() {

  

  if(count==(dSize-1) and !done) { //if done reading and they have not been written to SD card yet

    removeDCOffset(aDCVal, dSize, 8); //this function removes DC offset if you are measuring an AC signal

    SD.begin(chipSelect); //start SD card library

    File myFile = SD.open((wFile + ".csv"), FILE_WRITE); //open file to write data to CSV file

    if (myFile) {

      float sTime = 0;

      for (int y = 0; y < dSize; y++) {

        myFile.print(sTime,5); //write each reading to SD card as string

        myFile.print(",");

        myFile.println(String(aDCVal[y])+","); //write each reading to SD card as string

        sTime = sTime + period; //update signal period info

      }

    }

    myFile.close(); //close file

    done = true; //we are done 

  }

}

//function for configuring ports or pins, note that this will not use the same pin numbering scheme as Arduino

void portSetup() {

  // Input pin for ADC Arduino A0/PA02

  REG_PORT_DIRCLR1 = PORT_PA02;

  // Enable multiplexing on PA02_AIN0 PA03/ADC_VREFA

  PORT->Group[0].PINCFG[2].bit.PMUXEN = 1;

  PORT->Group[0].PINCFG[3].bit.PMUXEN = 1;

  PORT->Group[0].PMUX[1].reg = PORT_PMUX_PMUXE_B | PORT_PMUX_PMUXO_B;

}

//this function sets up the generic clock that will be used for the ADC unit

//by default it uses the 48M system clock, input arguments set divide factor for generic clock and choose which generic clock

//Note unless you understand how the clock system works use clock 3. clocks 5 and up can brick the microcontroller based on how Arduino configures things

void genericClockSetup(int clk, int dFactor) {

  // Enable the APBC clock for the ADC

  REG_PM_APBCMASK |= PM_APBCMASK_ADC;

  

  //This allows you to setup a div factor for the selected clock certain clocks allow certain division factors: Generic clock generators 3 - 8 8 division factor bits - DIV[7:0]

  GCLK->GENDIV.reg |= GCLK_GENDIV_ID(clk)| GCLK_GENDIV_DIV(dFactor);

  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);  

  //configure the generator of the generic clock with 48MHz clock

  GCLK->GENCTRL.reg |= GCLK_GENCTRL_GENEN | GCLK_GENCTRL_SRC_DFLL48M | GCLK_GENCTRL_ID(clk); // GCLK_GENCTRL_DIVSEL don't need this, it makes divide based on power of two

  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);

  

  //enable clock, set gen clock number, and ID to where the clock goes (30 is ADC)

  GCLK->CLKCTRL.reg |= GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN(clk) | GCLK_CLKCTRL_ID(30);

  while (GCLK->STATUS.bit.SYNCBUSY);

}

/*

ADC_CTRLB_PRESCALER_DIV4_Val    0x0u  

ADC_CTRLB_PRESCALER_DIV8_Val    0x1u   

ADC_CTRLB_PRESCALER_DIV16_Val   0x2u   

ADC_CTRLB_PRESCALER_DIV32_Val   0x3u   

ADC_CTRLB_PRESCALER_DIV64_Val   0x4u   

ADC_CTRLB_PRESCALER_DIV128_Val  0x5u   

ADC_CTRLB_PRESCALER_DIV256_Val  0x6u   

ADC_CTRLB_PRESCALER_DIV512_Val  0x7u   

--> 8 bit ADC measurement takes 5 clock cycles, 10 bit ADC measurement takes 6 clock cycles

--> Using 48MHz system clock with division factor of 1

--> Using ADC division factor of 32

--> Sample rate = 48M / (5 x 32) = 300 KSPS

This function sets up the ADC, including setting resolution and ADC sample rate

*/

void aDCSetup() {

  // Select reference

  REG_ADC_REFCTRL = ADC_REFCTRL_REFSEL_INTVCC1; //set vref for ADC to VCC

  // Average control 1 sample, no right-shift

  REG_ADC_AVGCTRL |= ADC_AVGCTRL_SAMPLENUM_1;

  // Sampling time, no extra sampling half clock-cycles

  REG_ADC_SAMPCTRL = ADC_SAMPCTRL_SAMPLEN(0);

  

  // Input control and input scan

  REG_ADC_INPUTCTRL |= ADC_INPUTCTRL_GAIN_1X | ADC_INPUTCTRL_MUXNEG_GND | ADC_INPUTCTRL_MUXPOS_PIN0;

  // Wait for synchronization

  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);

  ADC->CTRLB.reg |= ADC_CTRLB_RESSEL_8BIT | ADC_CTRLB_PRESCALER_DIV32 | ADC_CTRLB_FREERUN; //This is where you set the divide factor, note that the divide call has no effect until you change Arduino wire.c

  //Wait for synchronization

  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);

  ADC->WINCTRL.reg = ADC_WINCTRL_WINMODE_DISABLE; // Disable window monitor mode

  while(ADC->STATUS.bit.SYNCBUSY);

  ADC->EVCTRL.reg |= ADC_EVCTRL_STARTEI; //start ADC when event occurs

  while (ADC->STATUS.bit.SYNCBUSY);

  ADC->CTRLA.reg |= ADC_CTRLA_ENABLE; //set ADC to run in standby

  while (ADC->STATUS.bit.SYNCBUSY);

}

//This function sets up an ADC interrupt that is triggered 

//when an ADC value is out of range of the window

//input argument is priority of interrupt (0 is highest priority)

void setUpInterrupt(byte priority) {

  

  ADC->INTENSET.reg |= ADC_INTENSET_RESRDY; // enable ADC ready interrupt

  while (ADC->STATUS.bit.SYNCBUSY);

  NVIC_EnableIRQ(ADC_IRQn); // enable ADC interrupts

  NVIC_SetPriority(ADC_IRQn, priority); //set priority of the interrupt

}

//software trigger to start ADC in free run

//in future could use this to set various ADC triggers

void aDCSWTrigger() {

  ADC->SWTRIG.reg |= ADC_SWTRIG_START;

}

//This ISR is called each time ADC makes a reading

void ADC_Handler() {

    if(count<1023) {

      aDCVal[count] = REG_ADC_RESULT;

      count++;

    }

    ADC->INTFLAG.reg = ADC_INTENSET_RESRDY; //Need to reset interrupt

}

//This function takes out DC offset of AC signal, it assumes that the offset brings signal to zero volts

//input arguments: array with measured points and bits of measurement

void removeDCOffset(volatile int aDC[], int aSize, int bits) {

  int aSteps = pow(2,bits)/2; //get number of levels in ADC measurement and cut it in half

  for(int i=0; i<aSize; i++) {

    aDC[i] = aDC[i] - aSteps; //take out offset

  }

}

Utilizing Advanced ADC Capabilities on Arduino’s with the SAMD21 (Zero, MKR1000, etc) Part 1

We are all familiar with the Arduino "analogRead()" function, but there is a lot more to the SAMD21 ADC then just taking simple readings. In this video series we look at some of the more advanced ADC capabilities of the SAMD21 and how to use them. In part 1 we look at how to use the window monitoring capability of the ADC.

//*******************Arduino code from the video*********************
//This sketch is from a tutorial on the ForceTronics YouTube Channel called 
//Utilizing Advanced ADC Capabilities on Arduino’s with the SAMD21 (Zero, MKR1000, etc)
//This code is public domain and free to anyone to use or modify at your own risk

//declare const for window mode settings
const byte DISABLE = 0;
const byte MODE1 = 1;
const byte MODE2 = 2;
const byte MODE3 = 3;
const byte MODE4 = 4;

void setup() {
  //call this function to start the ADC in window and define the window parameters
  ADCWindowBegin(MODE1, 512, 750); //Do not use the Arduino analog functions until you call ADCWindowEnd()
  Serial.begin(57600);
}

void loop() {
  delay(1500);
  Serial.println(readADC()); //the "readADC()" function can be used to get ADC readings while in Window mode
  Serial.println();
}

//This is the interrupt service routine (ISR) that is called 
//if an ADC measurement falls out of the range of the window 
void ADC_Handler() {
    digitalWrite(LED_BUILTIN, HIGH); //turn LED off
    ADC->INTFLAG.reg = ADC_INTFLAG_WINMON; //Need to reset interrupt
}

//this function sets up the ADC window mode with interrupt
void ADCWindowBegin(byte mode, int upper, int lower) {
  setMeasPin(); //function sets up ADC pin A0 as input
  setGenClock(); //setup ADC clock, using internal 8MHz clock
  setUPADC(); //configure ADC
  setADCWindow(mode, upper, lower); //setup ADC window mode 
  setUpInterrupt(0); //setup window mode interrupt with highest priority
  enableADC(1); //enable ADC 
}

void ADCWindowEnd() {
  NVIC_DisableIRQ(ADC_IRQn); //turn off interrupt
  enableADC(0); //disable ADC 
}

//setup measurement pin, using Arduino ADC pin A3
void setMeasPin() {
  // Input pin for ADC Arduino A3/PA04
  REG_PORT_DIRCLR1 = PORT_PA04;

  // Enable multiplexing on PA04
  PORT->Group[0].PINCFG[4].bit.PMUXEN = 1;
  PORT->Group[0].PMUX[1].reg = PORT_PMUX_PMUXE_B | PORT_PMUX_PMUXO_B;
}

//Function sets up generic clock for ADC
//Uses built-in 8MHz clock
void setGenClock() {
   // Enable the APBC clock for the ADC
  REG_PM_APBCMASK |= PM_APBCMASK_ADC;

  configOSC8M(); //this function sets up the internal 8MHz clock that we will use for the ADC
  
  // Setup clock GCLK3 for no div factor
   GCLK->GENDIV.reg |= GCLK_GENDIV_ID(3)| GCLK_GENDIV_DIV(1);
   while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);  

  //configure the generator of the generic clock, which is 8MHz clock
  GCLK->GENCTRL.reg |= GCLK_GENCTRL_GENEN | GCLK_GENCTRL_SRC_OSC8M | GCLK_GENCTRL_ID(3) | GCLK_GENCTRL_DIVSEL;
  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY);
  
  //enable clock, set gen clock number, and ID to where the clock goes (30 is ADC)
  GCLK->CLKCTRL.reg |= GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN(3) | GCLK_CLKCTRL_ID(30);
  while (GCLK->STATUS.bit.SYNCBUSY);
}

//Function that does general settings for ADC
//sets it for a single sample
//Uses internal voltage reference
//sets gain factor to 1/2
void setUPADC() {
  // Select reference, internal VCC/2
  ADC->REFCTRL.reg |= ADC_REFCTRL_REFSEL_INTVCC1; // VDDANA/2, combine with gain DIV2 for full VCC range

  // Average control 1 sample, no right-shift
  ADC->AVGCTRL.reg |= ADC_AVGCTRL_ADJRES(0) | ADC_AVGCTRL_SAMPLENUM_1;

  // Sampling time, no extra sampling half clock-cycles
  REG_ADC_SAMPCTRL |= ADC_SAMPCTRL_SAMPLEN(0);

  // Input control: set gain to div by two so ADC has measurement range of VCC, no diff measurement so set neg to gnd, pos input set to pin 0 or A0
  ADC->INPUTCTRL.reg |= ADC_INPUTCTRL_GAIN_DIV2 | ADC_INPUTCTRL_MUXNEG_GND | ADC_INPUTCTRL_MUXPOS_PIN4;
  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);

  // PS16, 8 MHz, ADC_CLK = 500 kHz, ADC sampling rate, single eded, 12 bit, free running, DIV2 gain, 7 ADC_CLKs, 14 usec
  ADC->CTRLB.reg |= ADC_CTRLB_PRESCALER_DIV16 | ADC_CTRLB_RESSEL_10BIT | ADC_CTRLB_FREERUN; // Run ADC continously, 7 ADC_CLKs, 14 usec
  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);
}

//This function is used to setup the ADC windowing mode
//inputs are the mode, upper window value, and lower window value
//
void setADCWindow(byte mode, int upper, int lower) {
  ADC->WINCTRL.reg = mode; //set window mode
  while (ADC->STATUS.bit.SYNCBUSY);

   ADC->WINUT.reg = upper; //set upper threshold
   while (ADC->STATUS.bit.SYNCBUSY);

   ADC->WINLT.reg = lower; //set lower threshold
   while (ADC->STATUS.bit.SYNCBUSY);
}

//This function sets up an ADC interrupt that is triggered 
//when an ADC value is out of range of the window
//input argument is priority of interrupt (0 is highest priority)
void setUpInterrupt(byte priority) {
  
  ADC->INTENSET.reg |= ADC_INTENSET_WINMON; // enable ADC window monitor interrupt
   while (ADC->STATUS.bit.SYNCBUSY);

   NVIC_EnableIRQ(ADC_IRQn); // enable ADC interrupts
   NVIC_SetPriority(ADC_IRQn, priority); //set priority of the interrupt
}

//function allows you to enable or disable ADC
void enableADC(bool en) {
  if(en) ADC->CTRLA.reg = 2; //2 is binary 010 which is register bit to enable ADC
  else ADC->CTRLA.reg = 0; //0 disables ADC
}

//This function will return the latest ADC reading made during free run window mode
//must first start the ADC before calling this function
unsigned int readADC() {
  // Free running, wait for conversion to complete
  while (!(REG_ADC_INTFLAG & ADC_INTFLAG_RESRDY));
  // Wait for synchronization before reading RESULT
  while (REG_ADC_STATUS & ADC_STATUS_SYNCBUSY);
  
  return REG_ADC_RESULT;
}

//function enables the 8MHz clock used for the ADC
void configOSC8M() 
{
  SYSCTRL->OSC8M.reg |= SYSCTRL_OSC8M_ENABLE;
}

Reducing Power Consumption on Arduino Zero, MKR1000, or any SAMD21 Arduino Part 1

In this multiple part series we look at how to reduce power consumption for battery powered designs that utilize Arduino's with the Atmel SAMD21 MCU (Zero, MKR1000, etc). In part one we look at how to put the SAMD21 to sleep and wake it up with either the real time clock (RTC) or an external event on an input pin.

//***************Arduino Sketch from the video*********************.
//This code was used for a tutorial on the ForceTronics YouTube channel. It shows how to save power
//by putting Arduino's based on the SAMD21 MCU (MKR1000, Zero, etc) to sleep and how to wake them
//This code is public domain for anybody to use or modify

//#include "RTCZero.h"
#include <RTCZero.h>

/* Create an rtc object */
RTCZero rtc;

/* Change these values to set the current initial time */
const byte seconds = 0;
const byte minutes = 00;
const byte hours = 00;

/* Change these values to set the current initial date */
const byte day = 24;
const byte month = 9;
const byte year = 16;

void setup() 
{
  delay(5000); //delay so we can see normal current draw
   pinMode(LED_BUILTIN, OUTPUT); //set LED pin to output
  digitalWrite(LED_BUILTIN, LOW); //turn LED off

  rtc.begin(); //Start RTC library, this is where the clock source is initialized

  rtc.setTime(hours, minutes, seconds); //set time
  rtc.setDate(day, month, year); //set date

  rtc.setAlarmTime(00, 00, 10); //set alarm time to go off in 10 seconds
  
  //following two lines enable alarm, comment both out if you want to do external interrupt
  rtc.enableAlarm(rtc.MATCH_HHMMSS); //set alarm
  rtc.attachInterrupt(ISR); //creates an interrupt that wakes the SAMD21 which is triggered by a FTC alarm
  //comment out the below line if you are using RTC alarm for interrupt
 // extInterrupt(A1); //creates an interrupt source on external pin
  
  //puts SAMD21 to sleep
  rtc.standbyMode(); //library call
  //samSleep(); //function to show how call works
}

void loop() 
{
  //do nothing in main loop
}

//interrupt service routine (ISR), called when interrupt is triggered 
//executes after MCU wakes up
void ISR()
{
  digitalWrite(LED_BUILTIN, HIGH);
}


//function that sets up external interrupt
void extInterrupt(int interruptPin) {
  pinMode(interruptPin, INPUT_PULLUP);
  attachInterrupt(interruptPin, ISR, LOW);
}

//function to show how to put the 
void samSleep()
{
  // Set the sleep mode to standby
  SCB->SCR |= SCB_SCR_SLEEPDEEP_Msk;
  // SAMD sleep
  __WFI();
}

//**********************Changed "begin" function from RTCZero Library**************
void RTCZero::begin(bool resetTime)
{
  uint16_t tmp_reg = 0;
  
  PM->APBAMASK.reg |= PM_APBAMASK_RTC; // turn on digital interface clock
  //config32kOSC();

  // If the RTC is in clock mode and the reset was
  // not due to POR or BOD, preserve the clock time
  // POR causes a reset anyway, BOD behaviour is?
  bool validTime = false;
  RTC_MODE2_CLOCK_Type oldTime;

  if ((!resetTime) && (PM->RCAUSE.reg & (PM_RCAUSE_SYST | PM_RCAUSE_WDT | PM_RCAUSE_EXT))) {
    if (RTC->MODE2.CTRL.reg & RTC_MODE2_CTRL_MODE_CLOCK) {

      validTime = true;
      oldTime.reg = RTC->MODE2.CLOCK.reg;
    }
  }
  // Setup clock GCLK2 with OSC32K divided by 32
  GCLK->GENDIV.reg = GCLK_GENDIV_ID(2)|GCLK_GENDIV_DIV(4);
  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY)
    ;                                                         /*XOSC32K*/
  GCLK->GENCTRL.reg = (GCLK_GENCTRL_GENEN | GCLK_GENCTRL_SRC_OSCULP32K | GCLK_GENCTRL_ID(2) | GCLK_GENCTRL_DIVSEL );
  while (GCLK->STATUS.reg & GCLK_STATUS_SYNCBUSY)
    ;
  GCLK->CLKCTRL.reg = (uint32_t)((GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN_GCLK2 | (RTC_GCLK_ID << GCLK_CLKCTRL_ID_Pos)));
  while (GCLK->STATUS.bit.SYNCBUSY)
    ;

  RTCdisable();

  RTCreset();

  tmp_reg |= RTC_MODE2_CTRL_MODE_CLOCK; // set clock operating mode
  tmp_reg |= RTC_MODE2_CTRL_PRESCALER_DIV1024; // set prescaler to 1024 for MODE2
  tmp_reg &= ~RTC_MODE2_CTRL_MATCHCLR; // disable clear on match
  
  //According to the datasheet RTC_MODE2_CTRL_CLKREP = 0 for 24h
  tmp_reg &= ~RTC_MODE2_CTRL_CLKREP; // 24h time representation

  RTC->MODE2.READREQ.reg &= ~RTC_READREQ_RCONT; // disable continuously mode

  RTC->MODE2.CTRL.reg = tmp_reg;
  while (RTCisSyncing())
    ;

  NVIC_EnableIRQ(RTC_IRQn); // enable RTC interrupt 
  NVIC_SetPriority(RTC_IRQn, 0x00);

  RTC->MODE2.INTENSET.reg |= RTC_MODE2_INTENSET_ALARM0; // enable alarm interrupt
  RTC->MODE2.Mode2Alarm[0].MASK.bit.SEL = MATCH_OFF; // default alarm match is off (disabled)
  
  while (RTCisSyncing())
    ;

  RTCenable();
  RTCresetRemove();

  // If desired and valid, restore the time value
  if ((!resetTime) && (validTime)) {
    RTC->MODE2.CLOCK.reg = oldTime.reg;
    while (RTCisSyncing())
      ;
  }

  _configured = true;
}

Programming Arduino Zero, MKR1000, or any SAMD21 Arduino via Registers

In this video we look at how to program registers on Arduino's based on the SAMD21 MCU, like the Zero and MKR1000. To do this we will leverage the Atmel ASF data structures. This is a great way to access capabilities in the SAMD21 that are not covered by Arduino libraries. The link to the ASF documentation is http://asf.atmel.com/docs/3.16.0/samd21/html/annotated.html

Arduino code from video:

bool tog = false; //variable to toggle digital output

int cDiv = 1; //varible to hold clock divider

int count = 0; //variable to track when to switch clock freq

void setup() {

  PM->CPUSEL.reg = PM_CPUSEL_CPUDIV(1); //Sets CPU frequency: power management struct, CPUSEL union, register variable

  pinMode(3, OUTPUT); //set D3 to output

}

void loop() {

  if(tog) tog = false; //if tog is true turn it false

  else tog =true;

  digitalWrite(3,tog); //set digital output

  count++;  

  if(count > 6) { //check if it is time to change clock frequency

    if(cDiv == 1) cDiv = 4;

    else cDiv = 1;

    PM->CPUSEL.reg = PM_CPUSEL_CPUDIV(cDiv); //PM_CPUSEL_CPUDIV_DIV4_Val

    count = 0;

  }

}

Advanced PWM for Arduino Zero or any Atmel SAMD21 Based Arduino Board

The Arduino PWM library leaves a lot to be desired since it really only scratches the surface on PWM capabilities built into today's MCUs. In this video we look at how to unlock some of the more advanced PWM features on any Arduino board based on the Atmel SAMD21 32 bit ARM MCU.

Click here to access the Atmel programming API from the video

Arduino code from video***********************************************************
//This was used for ForceTronics YouTube tutorial on generating PWM signals with SAMD21 based Arduinos
//This code is public domain and can be used by anyone at their own risk
//Some of this code was leveraged from MartinL on Arduino Forum http://forum.arduino.cc/index.php?topic=346731.5;wap2

//sets the period of the PWM signal, PWM period = wPer / gen clock rate 
volatile unsigned char wPer = 255;
//This variable is to generate the duty cycle of the PWM signal 0.5 --> 50%
volatile float pWMDC = .5;
//selects the gen clock for setting the waveform generator clock or sample rate
const unsigned char gClock = 4;
//sets the divide factor for the gen clk, 48MHz / 3 = 16MHz
const unsigned char dFactor = 3;

void setup() 
{ 
  pinMode(3, OUTPUT);
  analogReadResolution(8); //set the ADC resolution to match the PWM max resolution (0 to 255)
  
  REG_GCLK_GENDIV = GCLK_GENDIV_DIV(dFactor) |          // Divide the main clock down by some factor to get generic clock
                    GCLK_GENDIV_ID(gClock);            // Select Generic Clock (GCLK) 4
  while (GCLK->STATUS.bit.SYNCBUSY);              // Wait for synchronization

  REG_GCLK_GENCTRL = GCLK_GENCTRL_IDC |           
                     GCLK_GENCTRL_GENEN |         // Enable GCLK4
                     GCLK_GENCTRL_SRC_DFLL48M |   // Set the 48MHz clock source
                     GCLK_GENCTRL_ID(gClock);          // Select GCLK4
  while (GCLK->STATUS.bit.SYNCBUSY);              // Wait for synchronization

  // Enable the port multiplexer for the digital pin. Note commented out line is pin D7, other is D3
 // PORT->Group[g_APinDescription[7].ulPort].PINCFG[g_APinDescription[7].ulPin].bit.PMUXEN = 1;
  PORT->Group[g_APinDescription[3].ulPort].PINCFG[g_APinDescription[3].ulPin].bit.PMUXEN = 1;
  
   //Connect the TCC0 timer to digital output - port pins are paired odd PMUO and even PMUXE (note D7 is commented out and D3 is not)
  // PORT->Group[g_APinDescription[2].ulPort].PMUX[g_APinDescription[2].ulPin >> 1].reg = PORT_PMUX_PMUXO_F | PORT_PMUX_PMUXE_F; 
  PORT->Group[g_APinDescription[4].ulPort].PMUX[g_APinDescription[4].ulPin >> 1].reg = PORT_PMUX_PMUXO_F | PORT_PMUX_PMUXE_F;

  // Feed GCLK4 to TCC0 and TCC1
  REG_GCLK_CLKCTRL = GCLK_CLKCTRL_CLKEN |         // Enable GCLK4 to TCC0 and TCC1
                     GCLK_CLKCTRL_GEN_GCLK4 |     // Select GCLK4
                     GCLK_CLKCTRL_ID_TCC0_TCC1;   // Feed GCLK4 to TCC0 and TCC1
  while (GCLK->STATUS.bit.SYNCBUSY);              // Wait for synchronization

  //Set for Single slope PWM operation: timers or counters count up to TOP value and then repeat
  REG_TCC1_WAVE |= TCC_WAVE_WAVEGEN_NPWM;       // Reverse the output polarity on all TCC0 outputs
                   //TCC_WAVE_POL(0xF)      //this line inverts the output waveform
                   //TCC_WAVE_WAVEGEN_DSBOTH;    // Setup dual slope PWM on TCC0
  while (TCC1->SYNCBUSY.bit.WAVE);               // Wait for synchronization

  // Each timer counts up to a maximum or TOP value set by the PER register,
  // this determines the frequency of the PWM operation: 
  REG_TCC1_PER = wPer;         // This sets the rate or frequency of PWM signal. 
  while (TCC1->SYNCBUSY.bit.PER);                // Wait for synchronization
  
  // Set the PWM signal to output 50% duty cycle initially (0.5 x 255)
  REG_TCC1_CC1 = pWMDC*wPer;        
  while (TCC1->SYNCBUSY.bit.CC1);                // Wait for synchronization

  //enable interrupts
  REG_TCC1_INTENSET = TCC_INTENSET_OVF; //Set up interrupt at TOP of each PWM cycle
  enable_interrupts(); //enable in NVIC
  
  // Set prescaler and enable the outputs
  REG_TCC1_CTRLA |= TCC_CTRLA_PRESCALER_DIV1 |    // Divide GCLK4 by 1
                    TCC_CTRLA_ENABLE;             // Enable the TCC0 output
  while (TCC1->SYNCBUSY.bit.ENABLE);              // Wait for synchronization
}

void loop() { 

  //Put main code here
 }

//This function sets the interrupts priority to highest and then enables the PWM interrupt
void enable_interrupts() {
  NVIC_SetPriority(TCC1_IRQn, 0);    // Set the Nested Vector Interrupt Controller (NVIC) priority
  NVIC_EnableIRQ(TCC1_IRQn);
}

//This ISR is called at the end or TOP of each PWM cycle
void TCC1_Handler() {
    REG_TCC1_PER = analogRead(A1); //Get period from A1
    while (TCC1->SYNCBUSY.bit.PER);
    REG_TCC1_CC1 = (analogRead(A0)/255.0)*analogRead(A1); //calculate PWM using A0 reading and A1 current state
    while (TCC1->SYNCBUSY.bit.CC1);
    REG_TCC0_INTFLAG = TC_INTFLAG_OVF; //Need to reset interrupt
}

Pull-up and Pull-down Resistor Tutorial

In this post we take a look at what are pull-up and pull-down resistors, their purpose, and where to use them.

Arduino code from video:
void setup() {
  // put your setup code here, to run once:
  pinMode(3,INPUT);
  pinMode(6,INPUT_PULLUP);
  pinMode(5,INPUT);
  pinMode(4,INPUT);
  pinMode(2,INPUT);
  Serial.begin(57600);

}

void loop() {
  // put your main code here, to run repeatedly:
  Serial.print("This is the pull-up input D6 ");
  Serial.println(digitalRead(6));
  Serial.print("D5 input has no pull-up ");
  Serial.println(digitalRead(5));
   Serial.print("D4 input has no pull-up ");
  Serial.println(digitalRead(4));
  Serial.print("D3 input has no pull-up ");
  Serial.println(digitalRead(3));
   Serial.print("D2 input has no pull-up ");
  Serial.println(digitalRead(2));
  Serial.println();
  delay(1500);
}