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Difference between revisions of "Quadcopter"

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* 1 , [http://www.hobbyking.com/hobbyking/store/__8497__turnigy_s3317m_servo_26g_3_0kg_14sec.html Turnigy S3317M Servo 26g / 3.0kg / .14sec] ($7.20)
 
* 1 , [http://www.hobbyking.com/hobbyking/store/__8497__turnigy_s3317m_servo_26g_3_0kg_14sec.html Turnigy S3317M Servo 26g / 3.0kg / .14sec] ($7.20)
 
* 0.5 , EMS Express to Netherlands(MAX 2.5kg) ($27,325)
 
* 0.5 , EMS Express to Netherlands(MAX 2.5kg) ($27,325)
 +
* 0,5 , taxes (€)
  
 
random ebay shops
 
random ebay shops

Revision as of 12:43, 13 June 2013

Project: Quadcopter
Quadcopter Picture.jpg
Name Quadcopter
Initiator Michielbrink and Vondel
Status In progress
Skills lots of skills
Summary awesome quadcopter with a lot of sensors


The quadcopter

To give you an idea of what we are planning with our Quadcopter, here is a list of features we want to include:

  • gyroscope
  • accelerometer
  • compass
  • ultrasonic range sensors on every corner
  • control via wifi
  • live webcam stream
  • according to a comment with the motors we bought: at 1,3Kg, speed up to 75km/h
  • servo to tilt webcam.
  • battery measurement through adc -> uart on msp430g2553.
  • stm32f3 discovery board as brain.
  • raspberry pi for the webcam stream, control and more fun stuff
  • gps (in the distant future)
  • and lots more!


buy list

We ordered for two people but the prices are per person. so there are units at this list that are half.

hobbykings

random ebay shops

de firmware voor de msp430g2553 (adc naar uart)

    #include <msp430.h>
    #include <stdbool.h>
    #include <stdio.h>
 
    #define GND         BIT4
    #define DAT         BIT5
    #define RXD		    BIT1
    #define TXD		    BIT2
 
    char buffer[4];
    int adc_new;
    int adc_old;
    char * adc_string;
 
    void uart_putc(unsigned char c);
    void uart_puts(const char *str);
    int adc_read();
    void Delay_ms(unsigned int ms);
 
    int main(void)
    {
        //msp430 init
        WDTCTL = WDTPW + WDTHOLD;         // Stop WDT
        BCSCTL1 = CALBC1_1MHZ;            // Set DCO to 1MHz
        DCOCTL = CALDCO_1MHZ;  
 
        //pin init
        P1SEL  = RXD + TXD;                     
        P1SEL2 = RXD + TXD;
        P1DIR |= GND;
        P1OUT&=~GND;
 
        //uart init
        UCA0CTL1 |= UCSSEL_2;                     // SMCLK
        UCA0BR0 = 104;                            // 1MHz 9600
        UCA0BR1 = 0;                              // 1MHz 9600
        UCA0MCTL = UCBRS0;                        // Modulation UCBRSx = 1
        UCA0CTL1 &= ~UCSWRST;                     // Initialize USCI state machine
        IE2 |= UCA0RXIE;                          // Enable USCI_A0 RX interrupt  
 
        //adc init
        ADC10CTL1 = INCH_5 + ADC10DIV_3 ;         // Channel 5, ADC10CLK/4
        ADC10CTL0 = SREF_0 + ADC10SHT_3 + ADC10ON + ADC10IE;  //Vcc & Vss as reference
        ADC10AE0 |= BIT5;                         //P1.4 ADC option
 
        __enable_interrupt();
 
        Delay_ms(1);                   // Wait for ADC Ref to settle
 
        while(1)                    
        { 
            Delay_ms(500);  
            adc_new = adc_read()*10/1023;
            if(adc_new != adc_old)
            {
                sprintf(adc_string, "%d",adc_new);
                uart_puts(adc_string);
                adc_old = adc_new;
            }   
        }
    }
 
    //uart
 
    void uart_putc(unsigned char c)
    {
        while (!(IFG2&UCA0TXIFG));              // USCI_A0 TX buffer ready?
        UCA0TXBUF = c;                    		// TX
    }
 
    void uart_puts(const char *str)
    {
        while(*str) uart_putc(*str++);
    }
 
    //adc
 
    int adc_read()
    {                  
        ADC10CTL0 |= ENC + ADC10SC;             // Sampling and conversion start
        __bis_SR_register(CPUOFF + GIE);        // LPM0 with interrupts enabled
        return(ADC10MEM);
    }
 
    __attribute__((interrupt(ADC10_VECTOR)))
    void ADC10_ISR(void) 
    {
      __bic_SR_register_on_exit(CPUOFF);        // Return to active mode
    }
 
    //delay
 
    void Delay_ms(unsigned int ms)
    {
        while(ms--)
        {
        __delay_cycles(1000);
        }
    }