mirror
/
pimoroni-pico
kopia lustrzana https://github.com/pimoroni/pimoroni-pico
1
0
Forkuj 0
Kod Zgłoszenia Projekty Wydania Wiki Aktywność

Improvements to servo calibration and usage

pull/259/head
ZodiusInfuser 2022-02-16 10:28:47 +00:00
rodzic 2e58841b5e
commit d4012a271e
3 zmienionych plików z 211 dodań i 93 usunięć
Pokaż statystyki Ściągnij plik aktualizacji Ściągnij plik porównania Expand all files Collapse all files

240
drivers/servo/servo.cpp
Wyświetl plik

@ -10,9 +10,9 @@ namespace servo {
: pulse(pulse), value(value) {
}
Calibration::Calibration()
Calibration::Calibration(Type type)
: calibration(nullptr), calibration_points(0), limit_lower(true), limit_upper(true) {
create_default_calibration();
create_default_calibration(type);
}
Calibration::~Calibration() {
@ -22,8 +22,22 @@ namespace servo {
}
}
void Calibration::create_default_calibration() {
create_three_point_calibration(DEFAULT_MIN_PULSE, DEFAULT_MID_PULSE, DEFAULT_MAX_PULSE);
void Calibration::create_default_calibration(Type type) {
switch(type) {
default:
case ANGULAR:
create_three_point_calibration(DEFAULT_MIN_PULSE, DEFAULT_MID_PULSE, DEFAULT_MAX_PULSE,
-90.0f, 0.0f, +90.0f);
break;
case LINEAR:
create_two_point_calibration(DEFAULT_MIN_PULSE, DEFAULT_MAX_PULSE,
0.0f, 1.0f);
break;
case CONTINUOUS:
create_three_point_calibration(DEFAULT_MIN_PULSE, DEFAULT_MID_PULSE, DEFAULT_MAX_PULSE,
-1.0f, 0.0f, +1.0f);
break;
}
}
bool Calibration::create_blank_calibration(uint num_points) {
@ -39,11 +53,17 @@ namespace servo {
return success;
}
void Calibration::create_three_point_calibration(float minus_pulse, float zero_pulse, float plus_pulse, float value_extent) {
void Calibration::create_two_point_calibration(float min_pulse, float max_pulse, float min_value, float max_value) {
create_blank_calibration(2);
calibration[0] = CalibrationPoint(min_pulse, min_value);
calibration[1] = CalibrationPoint(max_pulse, max_value);
}
void Calibration::create_three_point_calibration(float min_pulse, float mid_pulse, float max_pulse, float min_value, float mid_value, float max_value) {
create_blank_calibration(3);
calibration[0] = CalibrationPoint(minus_pulse, -value_extent);
calibration[1] = CalibrationPoint(zero_pulse, 0.0f);
calibration[2] = CalibrationPoint(plus_pulse, +value_extent);
calibration[0] = CalibrationPoint(min_pulse, min_value);
calibration[1] = CalibrationPoint(mid_pulse, mid_value);
calibration[2] = CalibrationPoint(max_pulse, max_value);
}
bool Calibration::create_uniform_calibration(uint num_points, float min_pulse, float min_value, float max_pulse, float max_value) {
@ -85,25 +105,32 @@ namespace servo {
limit_upper = upper;
}
uint32_t Converter::pulse_to_level(float pulse, uint32_t resolution) {
if(pulse != 0) {
// Constrain the level to hardcoded limits to protect the servo
pulse = MIN(MAX(pulse, LOWER_HARD_LIMIT), UPPER_HARD_LIMIT);
float Converter::min_value() {
float value = 0.0f;
if(calibration_points >= 2) {
value = calibration[0].value;
}
return (uint32_t)((pulse * (float)resolution) / SERVO_PERIOD);
return value;
}
uint32_t Converter::pulse_to_level(uint16_t pulse, uint32_t resolution) {
if(pulse != 0) {
// Constrain the level to hardcoded limits to protect the servo
pulse = MIN(MAX(pulse, LOWER_HARD_LIMIT_I), UPPER_HARD_LIMIT_I);
float Converter::mid_value() {
float value = 0.0f;
if(calibration_points >= 2) {
value = (calibration[0].value + calibration[calibration_points - 1].value) / 2.0f;
}
return (uint32_t)(((uint64_t)pulse * (uint64_t)resolution) / SERVO_PERIOD);
return value;
}
float Converter::max_value() {
float value = 0.0f;
if(calibration_points >= 2) {
value = calibration[calibration_points - 1].value;
}
return value;
}
float Converter::value_to_pulse(float value) {
float pulse = 0;
float pulse = 0.0f;
if(calibration_points >= 2) {
uint8_t last = calibration_points - 1;
@ -113,7 +140,7 @@ namespace servo {
if(limit_lower)
pulse = calibration[0].pulse;
else
pulse = map_pulse(value, calibration[0].value, calibration[1].value,
pulse = map_float(value, calibration[0].value, calibration[1].value,
calibration[0].pulse, calibration[1].pulse);
}
// Is the value above the top most calibration point?
@ -122,14 +149,14 @@ namespace servo {
if(limit_upper)
pulse = calibration[last].pulse;
else
pulse = map_pulse(value, calibration[last - 1].value, calibration[last].value,
pulse = map_float(value, calibration[last - 1].value, calibration[last].value,
calibration[last - 1].pulse, calibration[last].pulse);
}
else {
// The value must between two calibration points, so iterate through them to find which ones
for(uint8_t i = 0; i < last; i++) {
if(value <= calibration[i + 1].value) {
pulse = map_pulse(value, calibration[i].value, calibration[i + 1].value,
pulse = map_float(value, calibration[i].value, calibration[i + 1].value,
calibration[i].pulse, calibration[i + 1].pulse);
break; // No need to continue checking so break out of the loop
}
@ -140,13 +167,57 @@ namespace servo {
return pulse;
}
float Converter::map_pulse(float value, float min_value, float max_value, float min_pulse, float max_pulse) {
return (((value - min_value) * (max_pulse - min_pulse)) / (max_value - min_value)) + min_pulse;
float Converter::value_from_pulse(float pulse) {
float value = 0.0f;
if(calibration_points >= 2) {
uint8_t last = calibration_points - 1;
// Is the pulse below the bottom most calibration point?
if(pulse < calibration[0].pulse) {
// Should the pulse be limited to the calibration or projected below it?
if(limit_lower)
value = calibration[0].value;
else
value = map_float(pulse, calibration[0].pulse, calibration[1].pulse,
calibration[0].value, calibration[1].value);
}
// Is the pulse above the top most calibration point?
else if(pulse > calibration[last].pulse) {
// Should the pulse be limited to the calibration or projected above it?
if(limit_upper)
value = calibration[last].value;
else
value = map_float(pulse, calibration[last - 1].pulse, calibration[last].pulse,
calibration[last - 1].value, calibration[last].value);
}
else {
// The pulse must between two calibration points, so iterate through them to find which ones
for(uint8_t i = 0; i < last; i++) {
if(pulse <= calibration[i + 1].pulse) {
value = map_float(pulse, calibration[i].pulse, calibration[i + 1].pulse,
calibration[i].value, calibration[i + 1].value);
break; // No need to continue checking so break out of the loop
}
}
}
}
return value;
}
Servo::Servo(uint pin)
: pin(pin) {
};
uint32_t Converter::pulse_to_level(float pulse, uint32_t resolution) {
// Constrain the level to hardcoded limits to protect the servo
pulse = MIN(MAX(pulse, LOWER_HARD_LIMIT), UPPER_HARD_LIMIT);
return (uint32_t)((pulse * (float)resolution) / SERVO_PERIOD);
}
float Converter::map_float(float in, float in_min, float in_max, float out_min, float out_max) {
return (((in - in_min) * (out_max - out_min)) / (in_max - in_min)) + out_min;
}
Servo::Servo(uint pin, Type type)
: pin(pin), converter(type) {
}
Servo::~Servo() {
gpio_set_function(pin, GPIO_FUNC_NULL);
@ -162,54 +233,85 @@ namespace servo {
pwm_init(pwm_gpio_to_slice_num(pin), &pwm_cfg, true);
gpio_set_function(pin, GPIO_FUNC_PWM);
pwm_set_gpio_level(pin, 0);
return true;
}
void Servo::set_value(float value) {
float pulse = converter.value_to_pulse(value);
uint16_t level = (uint16_t)converter.pulse_to_level(pulse, 20000);
pwm_set_gpio_level(pin, level);
bool Servo::is_enabled() {
return enabled;
}
// void RGBLED::set_brightness(uint8_t brightness) {
// led_brightness = brightness;
// update_pwm();
// }
void Servo::enable() {
if(last_enabled_pulse < MIN_VALID_PULSE) {
servo_value = converter.mid_value();
last_enabled_pulse = converter.value_to_pulse(servo_value);
}
pwm_set_gpio_level(pin, (uint16_t)converter.pulse_to_level(last_enabled_pulse, 20000));
enabled = true;
}
// void RGBLED::set_hsv(float h, float s, float v) {
// float i = floor(h * 6.0f);
// float f = h * 6.0f - i;
// v *= 255.0f;
// uint8_t p = v * (1.0f - s);
// uint8_t q = v * (1.0f - f * s);
// uint8_t t = v * (1.0f - (1.0f - f) * s);
void Servo::disable() {
pwm_set_gpio_level(pin, 0);
enabled = false;
}
// switch (int(i) % 6) {
// case 0: led_r = v; led_g = t; led_b = p; break;
// case 1: led_r = q; led_g = v; led_b = p; break;
// case 2: led_r = p; led_g = v; led_b = t; break;
// case 3: led_r = p; led_g = q; led_b = v; break;
// case 4: led_r = t; led_g = p; led_b = v; break;
// case 5: led_r = v; led_g = p; led_b = q; break;
// }
float Servo::get_value() {
return servo_value;
}
// update_pwm();
// }
void Servo::set_value(float value) {
servo_value = value;
float pulse = converter.value_to_pulse(value);
if(pulse >= MIN_VALID_PULSE) {
last_enabled_pulse = pulse;
pwm_set_gpio_level(pin, (uint16_t)converter.pulse_to_level(last_enabled_pulse, 20000));
enabled = true;
}
else {
disable();
}
}
// void RGBLED::update_pwm() {
// uint16_t r16 = GAMMA[led_r];
// uint16_t g16 = GAMMA[led_g];
// uint16_t b16 = GAMMA[led_b];
// r16 *= led_brightness;
// g16 *= led_brightness;
// b16 *= led_brightness;
// if(polarity == Polarity::ACTIVE_LOW) {
// r16 = UINT16_MAX - r16;
// g16 = UINT16_MAX - g16;
// b16 = UINT16_MAX - b16;
// }
// pwm_set_gpio_level(pin_r, r16);
// pwm_set_gpio_level(pin_g, g16);
// pwm_set_gpio_level(pin_b, b16);
// }
float Servo::get_pulse() {
return last_enabled_pulse;
}
void Servo::set_pulse(float pulse) {
if(pulse >= MIN_VALID_PULSE) {
servo_value = converter.value_from_pulse(pulse);
last_enabled_pulse = pulse;
pwm_set_gpio_level(pin, (uint16_t)converter.pulse_to_level(last_enabled_pulse, 20000));
enabled = true;
}
else {
disable();
}
}
void Servo::to_min() {
set_value(converter.min_value());
}
void Servo::to_mid() {
set_value(converter.mid_value());
}
void Servo::to_max() {
set_value(converter.max_value());
}
void Servo::to_percent(float in, float in_min, float in_max) {
float value = Converter::map_float(in, in_min, in_max, converter.min_value(), converter.max_value());
set_value(value);
}
void Servo::to_percent(float in, float in_min, float in_max, float value_min, float value_max) {
float value = Converter::map_float(in, in_min, in_max, value_min, value_max);
set_value(value);
}
Calibration& Servo::calibration() {
return converter;
}
};

60
drivers/servo/servo.hpp
Wyświetl plik

@ -10,6 +10,12 @@
namespace servo {
enum Type {
ANGULAR = 0,
LINEAR,
CONTINUOUS
};
class Calibration {
//--------------------------------------------------
// Constants
@ -45,7 +51,7 @@ namespace servo {
// Constructors/Destructor
//--------------------------------------------------
protected:
Calibration();
Calibration(Type type);
virtual ~Calibration();
@ -53,9 +59,10 @@ namespace servo {
// Methods
//--------------------------------------------------
public:
void create_default_calibration();
void create_default_calibration(Type type);
bool create_blank_calibration(uint num_points); // Must have at least two points
void create_three_point_calibration(float minus_pulse, float zero_pulse, float plus_pulse, float value_extent = DEFAULT_VALUE_EXTENT);
void create_two_point_calibration(float min_pulse, float max_pulse, float min_value, float max_value);
void create_three_point_calibration(float min_pulse, float mid_pulse, float max_pulse, float min_value, float mid_value, float max_value);
bool create_uniform_calibration(uint num_points, float min_pulse, float min_value, float max_pulse, float max_value); // Must have at least two points
uint points();
@ -84,17 +91,12 @@ namespace servo {
static constexpr float UPPER_HARD_LIMIT = 2500.0f; // The maximum microsecond pulse to send
static constexpr float SERVO_PERIOD = 1000000 / 50; // This is hardcoded as all servos *should* run at this frequency
//Integer equivalents
static const uint16_t LOWER_HARD_LIMIT_I = (uint16_t)LOWER_HARD_LIMIT;
static const uint16_t UPPER_HARD_LIMIT_I = (uint16_t)UPPER_HARD_LIMIT;
static const uint64_t SERVO_PERIOD_I = (uint64_t)SERVO_PERIOD;
//--------------------------------------------------
// Constructors/Destructor
//--------------------------------------------------
public:
Converter() : Calibration() {}
Converter(Type type) : Calibration(type) {}
virtual ~Converter() {}
@ -102,11 +104,14 @@ namespace servo {
// Methods
//--------------------------------------------------
public:
static uint32_t pulse_to_level(float pulse, uint32_t resolution);
static uint32_t pulse_to_level(uint16_t pulse, uint32_t resolution);
float min_value();
float mid_value();
float max_value();
float value_to_pulse(float value);
private:
static float map_pulse(float value, float min_value, float max_value, float min_pulse, float max_pulse);
float value_from_pulse(float pulse);
static uint32_t pulse_to_level(float pulse, uint32_t resolution);
static float map_float(float in, float in_min, float in_max, float out_min, float out_max);
};
class Servo {
@ -120,6 +125,8 @@ namespace servo {
static const uint32_t MAX_PWM_WRAP = UINT16_MAX;
static constexpr uint16_t MAX_PWM_DIVIDER = (1 << 7);
static constexpr float MIN_VALID_PULSE = 1.0f;
//--------------------------------------------------
// Variables
@ -130,7 +137,9 @@ namespace servo {
uint16_t pwm_period;
float pwm_frequency = DEFAULT_PWM_FREQUENCY;
float servo_angle = 0.0f;
float servo_value = 0.0f;
float last_enabled_pulse = 0.0f;
bool enabled = false;
Converter converter;
@ -139,7 +148,7 @@ namespace servo {
// Constructors/Destructor
//--------------------------------------------------
public:
Servo(uint pin);
Servo(uint pin, Type type = ANGULAR);
~Servo();
//--------------------------------------------------
@ -148,18 +157,23 @@ namespace servo {
public:
bool init();
void enable_servo();
void disable_servo();
bool is_enabled();
void enable();
void disable();
void set_pulse();
float get_value();
void set_value(float value);
Calibration& calibration() {
return converter;
}
float get_pulse();
void set_pulse(float pulse);
private:
//void update_pwm();
void to_min();
void to_mid();
void to_max();
void to_percent(float in, float in_min = 0.0f, float in_max = 1.0f);
void to_percent(float in, float in_min, float in_max, float value_min, float value_max);
Calibration& calibration();
};
}

4
examples/servo2040/servo2040_functions.cpp
Wyświetl plik

@ -85,7 +85,7 @@ int main() {
//pwms.set_chan_level(servo_seq, 2000);//toggle ? 2000 : 1000);
//pwms.set_chan_polarity(servo_seq, toggle);
//pwms.set_chan_offset(servo_seq, toggle ? 19000 : 0);
simple_servo.set_value(servo_seq);
simple_servo.set_pulse(servo_seq + 1500);
servo_seq++;
if(servo_seq >= 4) {
servo_seq = 0;
@ -93,7 +93,9 @@ int main() {
//pwms.set_wrap(toggle ? 30000 : 20000);
//float div = clock_get_hz(clk_sys) / (toggle ? 500000 : 5000000);
//pwms.set_clkdiv(div);
simple_servo.disable();
}
printf("Angle = %f, Pulse = %f, Enabled = %s\n", simple_servo.get_value(), simple_servo.get_pulse(), simple_servo.is_enabled() ? "true" : "false");
//pwms.load_pwm();
}