// // // hello.stepper.44.half.c // // half stepping hello-world // // Neil Gershenfeld // 11/14/10 // // (c) Massachusetts Institute of Technology 2010 // This work may be reproduced, modified, distributed, // performed, and displayed for any purpose. Copyright is // retained and must be preserved. The work is provided // as is; no warranty is provided, and users accept all // liability. // #include #include #define output(directions,pin) (directions |= pin) // set port direction for output #define set(port,pin) (port |= pin) // set port pin #define clear(port,pin) (port &= (~pin)) // clear port pin #define pin_test(pins,pin) (pins & pin) // test for port pin #define bit_test(byte,bit) (byte & (1 << bit)) // test for bit set #define MOSFET_port PORTA // MOSFET port #define MOSFET_direction DDRA // MOSFET direction #define brown (1 << PA0) // MOSFET output pins #define black (1 << PA1) // " #define yellow (1 << PA2) // " #define orange (1 << PA3) // " #define on_delay() _delay_us(50) // PWM on time #define off_delay() _delay_us(10) // PWM off time #define PWM_count 100 // number of PWM cycles static uint8_t count; // // yellow PWM pulse // void pulse_yellow() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, yellow); on_delay(); clear(MOSFET_port, yellow); off_delay(); } } // // black PWM pulse // void pulse_black() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, black); on_delay(); clear(MOSFET_port, black); off_delay(); } } // // orange PWM pulse // void pulse_orange() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, orange); on_delay(); clear(MOSFET_port, orange); off_delay(); } } // // brown PWM pulse // void pulse_brown() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, brown); on_delay(); clear(MOSFET_port, brown); off_delay(); } } // // yellow, brown PWM pulse // void pulse_yellow_brown() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, yellow); set(MOSFET_port, brown); on_delay(); clear(MOSFET_port, yellow); clear(MOSFET_port, brown); off_delay(); } } // // yellow, black PWM pulse // void pulse_yellow_black() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, yellow); set(MOSFET_port, black); on_delay(); clear(MOSFET_port, yellow); clear(MOSFET_port, black); off_delay(); } } // // orange, brown PWM pulse // void pulse_orange_brown() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, orange); set(MOSFET_port, brown); on_delay(); clear(MOSFET_port, orange); clear(MOSFET_port, brown); off_delay(); } } // // orange, black PWM pulse // void pulse_orange_black() { for (count = 0; count < PWM_count; ++count) { set(MOSFET_port, orange); set(MOSFET_port, black); on_delay(); clear(MOSFET_port, orange); clear(MOSFET_port, black); off_delay(); } } // // counter-clockwise step // void step_ccw() { pulse_brown(); pulse_orange_brown(); pulse_orange(); pulse_orange_black(); pulse_black(); pulse_yellow_black(); pulse_yellow(); pulse_yellow_brown(); } int main(void) { // // main // static uint8_t k, t; // // set clock divider to /1 // CLKPR = (1 << CLKPCE); CLKPR = (0 << CLKPS3) | (0 << CLKPS2) | (0 << CLKPS1) | (0 << CLKPS0); // // initialize MOSFET pins // clear(MOSFET_port, brown); output(MOSFET_direction, brown); clear(MOSFET_port, black); output(MOSFET_direction, black); clear(MOSFET_port, yellow); output(MOSFET_direction, yellow); clear(MOSFET_port, orange); output(MOSFET_direction, orange); // // main loop // while (1) { for ( t = 0; t < 1; ++t) { _delay_ms(1000); } for ( k = 0; k < 1; ++k) { step_ccw(); } } }