// // hello.mic.45.c // // electret microphone hello-world // 9600 baud FTDI interface // // Neil Gershenfeld 4/1/14 // (c) Massachusetts Institute of Technology 2014 // // 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 bit_delay_time 102 // bit delay for 9600 with overhead #define bit_delay() _delay_us(bit_delay_time) // RS232 bit delay #define half_bit_delay() _delay_us(bit_delay_time/2) // RS232 half bit delay #define char_delay() _delay_ms(10) // char delay #define serial_port PORTB #define serial_direction DDRB #define serial_pin_out (1 << PB2) #define NPTS 100 // points in buffer void put_char(volatile unsigned char *port, unsigned char pin, char txchar) { // // send character in txchar on port pin // assumes line driver (inverts bits) // // start bit // clear(*port,pin); bit_delay(); // // unrolled loop to write data bits // if bit_test(txchar,0) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,1) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,2) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,3) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,4) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,5) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,6) set(*port,pin); else clear(*port,pin); bit_delay(); if bit_test(txchar,7) set(*port,pin); else clear(*port,pin); bit_delay(); // // stop bit // set(*port,pin); bit_delay(); // // char delay // bit_delay(); } int main(void) { // // main // static unsigned char i,array_lo[NPTS],array_hi[NPTS]; // // set clock divider to /1 // CLKPR = (1 << CLKPCE); CLKPR = (0 << CLKPS3) | (0 << CLKPS2) | (0 << CLKPS1) | (0 << CLKPS0); // // initialize output pins // set(serial_port, serial_pin_out); output(serial_direction, serial_pin_out); // // init A/D // ADMUX = (0 << REFS2) | (1 << REFS1) | (0 << REFS0) // 1.1V ref | (0 << MUX3) | (1 << MUX2) | (1 << MUX1) | (1 << MUX0); // 20(PB4-PB3) ADCSRA = (1 << ADEN) // enable | (1 << ADPS2) | (1 << ADPS1) | (0 << ADPS0); // prescaler /64 ADCSRB = (1 << BIN); // bipolar mode // // main loop // while (1) { // // send framing // put_char(&serial_port, serial_pin_out, 1); char_delay(); put_char(&serial_port, serial_pin_out, 2); char_delay(); put_char(&serial_port, serial_pin_out, 3); char_delay(); put_char(&serial_port, serial_pin_out, 4); char_delay(); // // free-running sample loop // for (i = 0; i < NPTS; ++i) { // // initiate conversion // ADCSRA |= (1 << ADSC); // // wait for completion // while (ADCSRA & (1 << ADSC)) ; // // save result // array_lo[i] = ADCL; array_hi[i] = ADCH; } for (i = 0; i < NPTS; ++i) { // // send result // put_char(&serial_port, serial_pin_out, array_lo[i]); put_char(&serial_port, serial_pin_out, array_hi[i]); } } }