// You will need to install RP2040_PWM in the Arduino IDE first! #define F_CPU 204000000 #include "RP2040_PWM.h" #include "hardware/pll.h" #include "hardware/clocks.h" //////////////////////////////////// begin clock code #include "hardware/pll.h" #include "hardware/clocks.h" void set_sys_clock_pll(uint32_t vco_freq, uint post_div1, uint post_div2) { if (!running_on_fpga()) { clock_configure(clk_sys, CLOCKS_CLK_SYS_CTRL_SRC_VALUE_CLKSRC_CLK_SYS_AUX, CLOCKS_CLK_SYS_CTRL_AUXSRC_VALUE_CLKSRC_PLL_USB, 48 * MHZ, 48 * MHZ); pll_init(pll_sys, 1, vco_freq, post_div1, post_div2); uint32_t freq = vco_freq / (post_div1 * post_div2); // Configure clocks // CLK_REF = XOSC (12MHz) / 1 = 12MHz clock_configure(clk_ref, CLOCKS_CLK_REF_CTRL_SRC_VALUE_XOSC_CLKSRC, 0, // No aux mux 12 * MHZ, 12 * MHZ); // CLK SYS = PLL SYS (125MHz) / 1 = 125MHz clock_configure(clk_sys, CLOCKS_CLK_SYS_CTRL_SRC_VALUE_CLKSRC_CLK_SYS_AUX, CLOCKS_CLK_SYS_CTRL_AUXSRC_VALUE_CLKSRC_PLL_SYS, freq, freq); clock_configure(clk_peri, 0, // Only AUX mux on ADC CLOCKS_CLK_PERI_CTRL_AUXSRC_VALUE_CLKSRC_PLL_USB, 48 * MHZ, 48 * MHZ); } } bool check_sys_clock_khz(uint32_t freq_khz, uint *vco_out, uint *postdiv1_out, uint *postdiv_out) { uint crystal_freq_khz = clock_get_hz(clk_ref) / 1000; for (uint fbdiv = 320; fbdiv >= 16; fbdiv--) { uint vco = fbdiv * crystal_freq_khz; if (vco < 400000 || vco > 1600000) continue; for (uint postdiv1 = 7; postdiv1 >= 1; postdiv1--) { for (uint postdiv2 = postdiv1; postdiv2 >= 1; postdiv2--) { uint out = vco / (postdiv1 * postdiv2); if (out == freq_khz && !(vco % (postdiv1 * postdiv2))) { *vco_out = vco * 1000; *postdiv1_out = postdiv1; *postdiv_out = postdiv2; return true; } } } } return false; } static inline bool set_sys_clock_khz(uint32_t freq_khz, bool required) { uint vco, postdiv1, postdiv2; if (check_sys_clock_khz(freq_khz, &vco, &postdiv1, &postdiv2)) { set_sys_clock_pll(vco, postdiv1, postdiv2); return true; } else if (required) { panic("System clock of %u kHz cannot be exactly achieved", freq_khz); } return false; } //////////////////////////////////// end clock code RP2040_PWM* pwm; RP2040_PWM* led; void setup() { Serial.begin(9600); set_sys_clock_khz(204000, true); pwm = new RP2040_PWM(15, 1557000, 0); pwm->enablePWM(); uint16_t PWM_TOP = pwm->get_TOP(); uint16_t PWM_DIV = pwm->get_DIV(); uint16_t PWM_Level = 0; // setPWM_manual(uint8_t pin, uint16_t top, uint8_t div, uint16_t level, bool phaseCorrect = false) pwm->setPWM_manual(15, PWM_TOP, PWM_DIV, PWM_Level, true); led = new RP2040_PWM(LED_BUILTIN, 1557000, 100); led->enablePWM(); PWM_TOP = led->get_TOP(); PWM_DIV = led->get_DIV(); PWM_Level = 65535; // setPWM_manual(uint8_t pin, uint16_t top, uint8_t div, uint16_t level, bool phaseCorrect = false) led->setPWM_manual(LED_BUILTIN, PWM_TOP, PWM_DIV, PWM_Level, false); Serial.println(pwm->get_freq_CPU()); Serial.println(pwm->getActualFreq()); delay(200); } //long n = 0; //float m = 0; void loop() { float v = ((float) analogRead(26) / 4096.0 * 7 * 100.0); pwm->setPWM_DCPercentage_manual(15, v); v *= 2; led->setPWM_DCPercentage_manual(LED_BUILTIN, v); //n = n + 1; //if(m < v) { m = v; } //if(n % 100000 == 0) { //Serial.print(n); //Serial.println(": "); //Serial.println(m); //m = 0; //} }