Prusa-Firmware/Firmware/temp_model.h
Yuri D'Elia 70fd9a336b TM: Handle UVDL set/load/report/upgrade
- Expose TEMP_MODEL_fS and TEMP_MODEL_LAG as D and L respectively,
  initializing the default values based on the previous hard-coded
  values.
- Always round L to the effective sample lag to future-proof model
  upgrades or changes (the stored value _is_ the effective value).
- Introduce UV as a new linear term for PTC heaters, defaulting
  to an identity for model backward-compatibility.
2023-02-10 15:44:28 +01:00

120 lines
4.2 KiB
C++

// model-based temperature safety checker declarations
#ifndef TEMP_MGR_INTV
#error "this file is not a public interface, it should be used *only* within temperature.cpp!"
#endif
#include "planner.h"
constexpr uint8_t TEMP_MODEL_CAL_S = 60; // Maximum recording lenght during calibration (s)
constexpr uint8_t TEMP_MODEL_CAL_R_STEP = 4; // Fan interpolation steps during calibration
constexpr float TEMP_MODEL_fE = 0.05; // error filter (1st-order IIR factor)
// transport delay buffer size (samples)
constexpr uint8_t TEMP_MODEL_MAX_LAG_SIZE = 8; // * TEMP_MGR_INTV = 2160
// resistance values for all fan levels
constexpr uint8_t TEMP_MODEL_R_SIZE = (1 << FAN_SOFT_PWM_BITS);
static const float TEMP_MODEL_R_DEFAULT[TEMP_MODEL_R_SIZE] PROGMEM = TEMP_MODEL_Rv;
namespace temp_model {
struct model_data
{
// temporary buffers
float dT_lag_buf[TEMP_MODEL_MAX_LAG_SIZE]; // transport delay buffer
uint8_t dT_lag_idx = 0; // transport delay buffer index
float dT_err_prev = 0; // previous temperature delta error
float T_prev = 0; // last temperature extruder
// configurable parameters
float P; // heater power (W)
float U; // linear temperature coefficient (W/K/W)
float V; // linear temperature intercept (W/W)
float C; // heatblock capacitance (J/K)
float fS; // sim. 1st order IIR filter factor (f=100/27)
uint16_t L; // sim. response lag (ms)
float R[TEMP_MODEL_R_SIZE]; // heatblock resistance for all fan levels (K/W)
float Ta_corr; // ambient temperature correction (K)
// thresholds
float warn; // warning threshold (K/s)
float err; // error threshold (K/s)
// status flags
union
{
bool flags;
struct
{
bool uninitialized: 1; // model is not initialized
bool error: 1; // error threshold set
bool warning: 1; // warning threshold set
} flag_bits;
};
// pre-computed values (initialized via reset)
float C_i; // heatblock capacitance (precomputed dT/C)
float warn_s; // warning threshold (per sample)
float err_s; // error threshold (per sample)
// simulation functions
void reset(uint8_t heater_pwm, uint8_t fan_pwm, float heater_temp, float ambient_temp);
void step(uint8_t heater_pwm, uint8_t fan_pwm, float heater_temp, float ambient_temp);
};
static bool enabled; // model check enabled
static bool warn_beep = true; // beep on warning threshold
static model_data data; // default heater data
static bool calibrated(); // return calibration/model validity status
static void check(); // check and trigger errors or warnings based on current state
// warning state (updated from from isr context)
volatile static struct
{
float dT_err; // temperature delta error (per sample)
bool warning: 1; // warning condition
bool assert: 1; // warning is still asserted
} warning_state;
static void handle_warning(); // handle warnings from user context
#ifdef TEMP_MODEL_DEBUG
static struct
{
volatile struct
{
uint32_t stamp;
int8_t delta_ms;
uint8_t counter;
uint8_t cur_pwm;
float cur_temp;
float cur_amb;
} entry;
uint8_t serial;
bool enabled;
} log_buf;
static void log_usr(); // user log handler
static void log_isr(); // isr log handler
#endif
} // namespace temp_model
namespace temp_model_cal {
// recording scratch buffer
struct rec_entry
{
float temp; // heater temperature
uint8_t pwm; // heater PWM
};
constexpr uint16_t REC_BUFFER_SIZE = TEMP_MODEL_CAL_S / TEMP_MGR_INTV;
static rec_entry* const rec_buffer = (rec_entry*)block_buffer; // oh-hey, free memory!
static_assert(sizeof(rec_entry[REC_BUFFER_SIZE]) <= sizeof(block_buffer),
"recording length too long to fit within available buffer");
} // namespace temp_model_cal