Updated and Validated
[betaflight.git] / src / test / unit / pid_unittest.cc
blob93cc769817aaafbac511ffe367e7e67b125c9e97
1 /*
2 * This file is part of Cleanflight.
4 * Cleanflight is free software: you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation, either version 3 of the License, or
7 * (at your option) any later version.
9 * Cleanflight is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
14 * You should have received a copy of the GNU General Public License
15 * along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
18 #include <stdint.h>
19 #include <stdbool.h>
20 #include <limits.h>
21 #include <cmath>
23 #include "unittest_macros.h"
24 #include "gtest/gtest.h"
25 #include "build/debug.h"
27 bool simulatedAirmodeEnabled = true;
28 float simulatedSetpointRate[3] = { 0,0,0 };
29 float simulatedPrevSetpointRate[3] = { 0,0,0 };
30 float simulatedRcDeflection[3] = { 0,0,0 };
31 float simulatedMotorMixRange = 0.0f;
33 int16_t debug[DEBUG16_VALUE_COUNT];
34 uint8_t debugMode;
36 extern "C" {
37 #include "platform.h"
39 #include "build/debug.h"
41 #include "common/axis.h"
42 #include "common/maths.h"
43 #include "common/filter.h"
45 #include "config/config.h"
46 #include "config/config_reset.h"
48 #include "drivers/sound_beeper.h"
49 #include "drivers/time.h"
51 #include "fc/controlrate_profile.h"
52 #include "fc/core.h"
53 #include "fc/rc.h"
55 #include "fc/rc_controls.h"
56 #include "fc/runtime_config.h"
58 #include "flight/imu.h"
59 #include "flight/mixer.h"
60 #include "flight/pid.h"
61 #include "flight/pid_init.h"
63 #include "io/gps.h"
65 #include "pg/pg.h"
66 #include "pg/pg_ids.h"
68 #include "sensors/gyro.h"
69 #include "sensors/acceleration.h"
71 gyro_t gyro;
72 attitudeEulerAngles_t attitude;
74 PG_REGISTER(accelerometerConfig_t, accelerometerConfig, PG_ACCELEROMETER_CONFIG, 0);
75 PG_REGISTER(systemConfig_t, systemConfig, PG_SYSTEM_CONFIG, 2);
77 bool unitLaunchControlActive = false;
78 launchControlMode_e unitLaunchControlMode = LAUNCH_CONTROL_MODE_NORMAL;
80 float getMotorMixRange(void) { return simulatedMotorMixRange; }
81 float getSetpointRate(int axis) { return simulatedSetpointRate[axis]; }
82 bool isAirmodeActivated() { return simulatedAirmodeEnabled; }
83 float getRcDeflectionAbs(int axis) { return fabsf(simulatedRcDeflection[axis]); }
84 void systemBeep(bool) { }
85 bool gyroOverflowDetected(void) { return false; }
86 float getRcDeflection(int axis) { return simulatedRcDeflection[axis]; }
87 void beeperConfirmationBeeps(uint8_t) { }
88 bool isLaunchControlActive(void) {return unitLaunchControlActive; }
89 void disarm(flightLogDisarmReason_e) { }
90 float applyFeedforwardLimit(int axis, float value, float Kp, float currentPidSetpoint)
92 UNUSED(axis);
93 UNUSED(Kp);
94 UNUSED(currentPidSetpoint);
95 return value;
97 void feedforwardInit(const pidProfile_t) { }
98 float feedforwardApply(int axis, bool newRcFrame, feedforwardAveraging_t feedforwardAveraging)
100 UNUSED(newRcFrame);
101 UNUSED(feedforwardAveraging);
102 const float feedforwardTransitionFactor = pidGetFeedforwardTransitionFactor();
103 float setpointDelta = simulatedSetpointRate[axis] - simulatedPrevSetpointRate[axis];
104 setpointDelta *= feedforwardTransitionFactor > 0 ? MIN(1.0f, getRcDeflectionAbs(axis) * feedforwardTransitionFactor) : 1;
105 return setpointDelta;
107 bool shouldApplyFeedforwardLimits(int axis)
109 UNUSED(axis);
110 return true;
112 bool getShouldUpdateFeedforward() { return true; }
113 void initRcProcessing(void) { }
116 pidProfile_t *pidProfile;
118 int loopIter = 0;
120 // Always use same defaults for testing in future releases even when defaults change
121 void setDefaultTestSettings(void) {
122 pgResetAll();
123 pidProfile = pidProfilesMutable(1);
124 pidProfile->pid[PID_ROLL] = { 40, 40, 30, 65 };
125 pidProfile->pid[PID_PITCH] = { 58, 50, 35, 60 };
126 pidProfile->pid[PID_YAW] = { 70, 45, 20, 60 };
127 pidProfile->pid[PID_LEVEL] = { 50, 50, 75, 0 };
129 // Compensate for the upscaling done without 'use_integrated_yaw'
130 pidProfile->pid[PID_YAW].I = pidProfile->pid[PID_YAW].I / 2.5f;
132 pidProfile->pidSumLimit = PIDSUM_LIMIT;
133 pidProfile->pidSumLimitYaw = PIDSUM_LIMIT_YAW;
134 pidProfile->yaw_lowpass_hz = 0;
135 pidProfile->dterm_lpf1_static_hz = 100;
136 pidProfile->dterm_lpf2_static_hz = 0;
137 pidProfile->dterm_notch_hz = 260;
138 pidProfile->dterm_notch_cutoff = 160;
139 pidProfile->dterm_lpf1_type = FILTER_BIQUAD;
140 pidProfile->itermWindupPointPercent = 50;
141 pidProfile->pidAtMinThrottle = PID_STABILISATION_ON;
142 pidProfile->levelAngleLimit = 55;
143 pidProfile->feedforward_transition = 100;
144 pidProfile->yawRateAccelLimit = 100;
145 pidProfile->rateAccelLimit = 0;
146 pidProfile->antiGravityMode = ANTI_GRAVITY_SMOOTH;
147 pidProfile->itermThrottleThreshold = 250;
148 pidProfile->itermAcceleratorGain = 1000;
149 pidProfile->crash_time = 500;
150 pidProfile->crash_delay = 0;
151 pidProfile->crash_recovery_angle = 10;
152 pidProfile->crash_recovery_rate = 100;
153 pidProfile->crash_dthreshold = 50;
154 pidProfile->crash_gthreshold = 400;
155 pidProfile->crash_setpoint_threshold = 350;
156 pidProfile->crash_recovery = PID_CRASH_RECOVERY_OFF;
157 pidProfile->horizon_tilt_effect = 75;
158 pidProfile->horizon_tilt_expert_mode = false;
159 pidProfile->crash_limit_yaw = 200;
160 pidProfile->itermLimit = 150;
161 pidProfile->throttle_boost = 0;
162 pidProfile->throttle_boost_cutoff = 15;
163 pidProfile->iterm_rotation = false;
164 pidProfile->iterm_relax = ITERM_RELAX_OFF,
165 pidProfile->iterm_relax_cutoff = 11,
166 pidProfile->iterm_relax_type = ITERM_RELAX_SETPOINT,
167 pidProfile->abs_control_gain = 0,
168 pidProfile->launchControlMode = LAUNCH_CONTROL_MODE_NORMAL,
169 pidProfile->launchControlGain = 40,
170 pidProfile->level_race_mode = false,
172 gyro.targetLooptime = 8000;
175 timeUs_t currentTestTime(void) {
176 return targetPidLooptime * loopIter++;
179 void resetTest(void) {
180 loopIter = 0;
181 pidRuntime.tpaFactor = 1.0f;
182 simulatedMotorMixRange = 0.0f;
184 pidStabilisationState(PID_STABILISATION_OFF);
185 DISABLE_ARMING_FLAG(ARMED);
187 setDefaultTestSettings();
188 for (int axis = FD_ROLL; axis <= FD_YAW; axis++) {
189 pidData[axis].P = 0;
190 pidData[axis].I = 0;
191 pidData[axis].D = 0;
192 pidData[axis].F = 0;
193 pidData[axis].Sum = 0;
194 simulatedSetpointRate[axis] = 0;
195 simulatedRcDeflection[axis] = 0;
196 gyro.gyroADCf[axis] = 0;
198 attitude.values.roll = 0;
199 attitude.values.pitch = 0;
200 attitude.values.yaw = 0;
202 flightModeFlags = 0;
203 unitLaunchControlActive = false;
204 pidProfile->launchControlMode = unitLaunchControlMode;
205 pidInit(pidProfile);
206 loadControlRateProfile();
208 currentControlRateProfile->levelExpo[FD_ROLL] = 0;
209 currentControlRateProfile->levelExpo[FD_PITCH] = 0;
211 // Run pidloop for a while after reset
212 for (int loop = 0; loop < 20; loop++) {
213 pidController(pidProfile, currentTestTime());
217 void setStickPosition(int axis, float stickRatio) {
218 simulatedPrevSetpointRate[axis] = simulatedSetpointRate[axis];
219 simulatedSetpointRate[axis] = 1998.0f * stickRatio;
220 simulatedRcDeflection[axis] = stickRatio;
223 // All calculations will have 10% tolerance
224 float calculateTolerance(float input) {
225 return fabsf(input * 0.1f);
228 TEST(pidControllerTest, testInitialisation)
230 resetTest();
232 // In initial state PIDsums should be 0
233 for (int axis = 0; axis <= FD_YAW; axis++) {
234 EXPECT_FLOAT_EQ(0, pidData[axis].P);
235 EXPECT_FLOAT_EQ(0, pidData[axis].I);
236 EXPECT_FLOAT_EQ(0, pidData[axis].D);
240 TEST(pidControllerTest, testStabilisationDisabled) {
241 ENABLE_ARMING_FLAG(ARMED);
242 // Run few loops to make sure there is no error building up when stabilisation disabled
244 for (int loop = 0; loop < 10; loop++) {
245 pidController(pidProfile, currentTestTime());
247 // PID controller should not do anything, while stabilisation disabled
248 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].P);
249 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].P);
250 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
251 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].I);
252 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].I);
253 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
254 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
255 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
256 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
260 TEST(pidControllerTest, testPidLoop) {
261 // Make sure to start with fresh values
262 resetTest();
263 ENABLE_ARMING_FLAG(ARMED);
264 pidStabilisationState(PID_STABILISATION_ON);
266 pidController(pidProfile, currentTestTime());
268 // Loop 1 - Expecting zero since there is no error
269 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].P);
270 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].P);
271 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
272 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].I);
273 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].I);
274 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
275 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
276 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
277 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
279 // Add some rotation on ROLL to generate error
280 gyro.gyroADCf[FD_ROLL] = 100;
281 pidController(pidProfile, currentTestTime());
283 // Loop 2 - Expect PID loop reaction to ROLL error
284 EXPECT_NEAR(-128.1, pidData[FD_ROLL].P, calculateTolerance(-128.1));
285 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].P);
286 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
287 EXPECT_NEAR(-7.8, pidData[FD_ROLL].I, calculateTolerance(-7.8));
288 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].I);
289 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
290 EXPECT_NEAR(-198.4, pidData[FD_ROLL].D, calculateTolerance(-198.4));
291 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
292 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
294 // Add some rotation on PITCH to generate error
295 gyro.gyroADCf[FD_PITCH] = -100;
296 pidController(pidProfile, currentTestTime());
298 // Loop 3 - Expect PID loop reaction to PITCH error, ROLL is still in error
299 EXPECT_NEAR(-128.1, pidData[FD_ROLL].P, calculateTolerance(-128.1));
300 EXPECT_NEAR(185.8, pidData[FD_PITCH].P, calculateTolerance(185.8));
301 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
302 EXPECT_NEAR(-15.6, pidData[FD_ROLL].I, calculateTolerance(-15.6));
303 EXPECT_NEAR(9.8, pidData[FD_PITCH].I, calculateTolerance(9.8));
304 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
305 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
306 EXPECT_NEAR(231.4, pidData[FD_PITCH].D, calculateTolerance(231.4));
307 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
309 // Add some rotation on YAW to generate error
310 gyro.gyroADCf[FD_YAW] = 100;
311 pidController(pidProfile, currentTestTime());
313 // Loop 4 - Expect PID loop reaction to PITCH error, ROLL and PITCH are still in error
314 EXPECT_NEAR(-128.1, pidData[FD_ROLL].P, calculateTolerance(-128.1));
315 EXPECT_NEAR(185.8, pidData[FD_PITCH].P, calculateTolerance(185.8));
316 EXPECT_NEAR(-224.2, pidData[FD_YAW].P, calculateTolerance(-224.2));
317 EXPECT_NEAR(-23.5, pidData[FD_ROLL].I, calculateTolerance(-23.5));
318 EXPECT_NEAR(19.6, pidData[FD_PITCH].I, calculateTolerance(19.6));
319 EXPECT_NEAR(-8.7, pidData[FD_YAW].I, calculateTolerance(-8.7));
320 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
321 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
322 EXPECT_NEAR(-132.25, pidData[FD_YAW].D, calculateTolerance(-132.25));
324 // Simulate Iterm behaviour during mixer saturation
325 simulatedMotorMixRange = 1.2f;
326 pidController(pidProfile, currentTestTime());
327 EXPECT_NEAR(-31.3, pidData[FD_ROLL].I, calculateTolerance(-31.3));
328 EXPECT_NEAR(29.3, pidData[FD_PITCH].I, calculateTolerance(29.3));
329 EXPECT_NEAR(-8.8, pidData[FD_YAW].I, calculateTolerance(-8.8));
330 simulatedMotorMixRange = 0;
332 // Match the stick to gyro to stop error
333 simulatedSetpointRate[FD_ROLL] = 100;
334 simulatedSetpointRate[FD_PITCH] = -100;
335 simulatedSetpointRate[FD_YAW] = 100;
337 for(int loop = 0; loop < 5; loop++) {
338 pidController(pidProfile, currentTestTime());
340 // Iterm is stalled as it is not accumulating anymore
341 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].P);
342 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].P);
343 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
344 EXPECT_NEAR(-31.3, pidData[FD_ROLL].I, calculateTolerance(-31.3));
345 EXPECT_NEAR(29.3, pidData[FD_PITCH].I, calculateTolerance(29.3));
346 EXPECT_NEAR(-10.6, pidData[FD_YAW].I, calculateTolerance(-10.6));
347 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
348 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
349 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
351 // Now disable Stabilisation
352 pidStabilisationState(PID_STABILISATION_OFF);
353 pidController(pidProfile, currentTestTime());
355 // Should all be zero again
356 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].P);
357 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].P);
358 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
359 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].I);
360 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].I);
361 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
362 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
363 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
364 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
367 TEST(pidControllerTest, testPidLevel) {
368 // Make sure to start with fresh values
369 resetTest();
370 ENABLE_ARMING_FLAG(ARMED);
371 pidStabilisationState(PID_STABILISATION_ON);
373 // Test Angle mode response
374 enableFlightMode(ANGLE_MODE);
375 float currentPidSetpoint = 30;
376 rollAndPitchTrims_t angleTrim = { { 0, 0 } };
378 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
379 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
380 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
381 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
383 // Test attitude response
384 setStickPosition(FD_ROLL, 1.0f);
385 setStickPosition(FD_PITCH, -1.0f);
386 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
387 EXPECT_FLOAT_EQ(275, currentPidSetpoint);
388 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
389 EXPECT_FLOAT_EQ(-275, currentPidSetpoint);
391 setStickPosition(FD_ROLL, -0.5f);
392 setStickPosition(FD_PITCH, 0.5f);
393 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
394 EXPECT_FLOAT_EQ(-137.5, currentPidSetpoint);
395 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
396 EXPECT_FLOAT_EQ(137.5, currentPidSetpoint);
398 attitude.values.roll = -275;
399 attitude.values.pitch = 275;
400 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
401 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
402 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
403 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
405 // Disable ANGLE_MODE
406 disableFlightMode(ANGLE_MODE);
407 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
408 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
409 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
410 EXPECT_FLOAT_EQ(0, currentPidSetpoint);
412 // Test level mode expo
413 enableFlightMode(ANGLE_MODE);
414 attitude.values.roll = 0;
415 attitude.values.pitch = 0;
416 setStickPosition(FD_ROLL, 0.5f);
417 setStickPosition(FD_PITCH, -0.5f);
418 currentControlRateProfile->levelExpo[FD_ROLL] = 50;
419 currentControlRateProfile->levelExpo[FD_PITCH] = 26;
420 currentPidSetpoint = pidLevel(FD_ROLL, pidProfile, &angleTrim, currentPidSetpoint);
421 EXPECT_FLOAT_EQ(85.9375, currentPidSetpoint);
422 currentPidSetpoint = pidLevel(FD_PITCH, pidProfile, &angleTrim, currentPidSetpoint);
423 EXPECT_FLOAT_EQ(-110.6875, currentPidSetpoint);
427 TEST(pidControllerTest, testPidHorizon) {
428 resetTest();
429 ENABLE_ARMING_FLAG(ARMED);
430 pidStabilisationState(PID_STABILISATION_ON);
431 enableFlightMode(HORIZON_MODE);
433 // Test full stick response
434 setStickPosition(FD_ROLL, 1.0f);
435 setStickPosition(FD_PITCH, -1.0f);
436 EXPECT_FLOAT_EQ(0, calcHorizonLevelStrength());
438 // Expect full rate output on full stick
439 // Test zero stick response
440 setStickPosition(FD_ROLL, 0);
441 setStickPosition(FD_PITCH, 0);
442 EXPECT_FLOAT_EQ(1, calcHorizonLevelStrength());
444 // Test small stick response
445 setStickPosition(FD_ROLL, 0.1f);
446 setStickPosition(FD_PITCH, -0.1f);
447 EXPECT_NEAR(0.82, calcHorizonLevelStrength(), calculateTolerance(0.82));
450 TEST(pidControllerTest, testMixerSaturation) {
451 resetTest();
452 ENABLE_ARMING_FLAG(ARMED);
453 pidStabilisationState(PID_STABILISATION_ON);
455 // Test full stick response
456 setStickPosition(FD_ROLL, 1.0f);
457 setStickPosition(FD_PITCH, -1.0f);
458 setStickPosition(FD_YAW, 1.0f);
459 simulatedMotorMixRange = 2.0f;
460 pidController(pidProfile, currentTestTime());
462 // Expect no iterm accumulation for yaw
463 EXPECT_FLOAT_EQ(150, pidData[FD_ROLL].I);
464 EXPECT_FLOAT_EQ(-150, pidData[FD_PITCH].I);
465 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
467 // Test itermWindup limit (note: windup limit now only affects yaw)
468 // First store values without exceeding iterm windup limit
469 resetTest();
470 ENABLE_ARMING_FLAG(ARMED);
471 pidStabilisationState(PID_STABILISATION_ON);
472 setStickPosition(FD_ROLL, 0.1f);
473 setStickPosition(FD_PITCH, -0.1f);
474 setStickPosition(FD_YAW, 0.1f);
475 simulatedMotorMixRange = 0.0f;
476 pidController(pidProfile, currentTestTime());
477 float rollTestIterm = pidData[FD_ROLL].I;
478 float pitchTestIterm = pidData[FD_PITCH].I;
479 float yawTestIterm = pidData[FD_YAW].I;
481 // Now compare values when exceeding the limit
482 resetTest();
483 ENABLE_ARMING_FLAG(ARMED);
484 pidStabilisationState(PID_STABILISATION_ON);
485 setStickPosition(FD_ROLL, 0.1f);
486 setStickPosition(FD_PITCH, -0.1f);
487 setStickPosition(FD_YAW, 0.1f);
488 simulatedMotorMixRange = (pidProfile->itermWindupPointPercent + 1) / 100.0f;
489 pidController(pidProfile, currentTestTime());
490 EXPECT_FLOAT_EQ(pidData[FD_ROLL].I, rollTestIterm);
491 EXPECT_FLOAT_EQ(pidData[FD_PITCH].I, pitchTestIterm);
492 EXPECT_LT(pidData[FD_YAW].I, yawTestIterm);
495 // TODO - Add more scenarios
496 TEST(pidControllerTest, testCrashRecoveryMode) {
497 resetTest();
498 pidProfile->crash_recovery = PID_CRASH_RECOVERY_ON;
499 pidInit(pidProfile);
500 ENABLE_ARMING_FLAG(ARMED);
501 pidStabilisationState(PID_STABILISATION_ON);
502 sensorsSet(SENSOR_ACC);
504 EXPECT_FALSE(crashRecoveryModeActive());
506 int loopsToCrashTime = (int)((pidProfile->crash_time * 1000) / targetPidLooptime) + 1;
508 // generate crash detection for roll axis
509 gyro.gyroADCf[FD_ROLL] = 800;
510 simulatedMotorMixRange = 1.2f;
511 for (int loop =0; loop <= loopsToCrashTime; loop++) {
512 gyro.gyroADCf[FD_ROLL] += gyro.gyroADCf[FD_ROLL];
513 // advance the time to avoid initialized state prevention of crash recovery
514 pidController(pidProfile, currentTestTime() + 2000000);
517 EXPECT_TRUE(crashRecoveryModeActive());
518 // Add additional verifications
521 TEST(pidControllerTest, testFeedForward) {
522 resetTest();
523 ENABLE_ARMING_FLAG(ARMED);
524 pidStabilisationState(PID_STABILISATION_ON);
526 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].F);
527 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].F);
528 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].F);
530 // Match the stick to gyro to stop error
531 setStickPosition(FD_ROLL, 1.0f);
532 setStickPosition(FD_PITCH, -1.0f);
533 setStickPosition(FD_YAW, -1.0f);
535 pidController(pidProfile, currentTestTime());
537 EXPECT_NEAR(2232.78, pidData[FD_ROLL].F, calculateTolerance(2232.78));
538 EXPECT_NEAR(-2061.03, pidData[FD_PITCH].F, calculateTolerance(-2061.03));
539 EXPECT_NEAR(-2061.03, pidData[FD_YAW].F, calculateTolerance(-2061.03));
541 // Match the stick to gyro to stop error
542 setStickPosition(FD_ROLL, 0.5f);
543 setStickPosition(FD_PITCH, -0.5f);
544 setStickPosition(FD_YAW, -0.5f);
546 pidController(pidProfile, currentTestTime());
548 EXPECT_NEAR(-558.20, pidData[FD_ROLL].F, calculateTolerance(-558.20));
549 EXPECT_NEAR(515.26, pidData[FD_PITCH].F, calculateTolerance(515.26));
550 EXPECT_NEAR(515.26, pidData[FD_YAW].F, calculateTolerance(515.26));
552 setStickPosition(FD_ROLL, 0.0f);
553 setStickPosition(FD_PITCH, 0.0f);
554 setStickPosition(FD_YAW, 0.0f);
556 for (int loop = 0; loop <= 15; loop++) {
557 gyro.gyroADCf[FD_ROLL] += gyro.gyroADCf[FD_ROLL];
558 pidController(pidProfile, currentTestTime());
561 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].F);
562 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].F);
563 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].F);
566 TEST(pidControllerTest, testItermRelax) {
567 resetTest();
568 pidProfile->iterm_relax = ITERM_RELAX_RP;
569 ENABLE_ARMING_FLAG(ARMED);
570 pidStabilisationState(PID_STABILISATION_ON);
572 pidProfile->iterm_relax_type = ITERM_RELAX_SETPOINT;
573 pidInit(pidProfile);
575 float itermErrorRate = 0;
576 float currentPidSetpoint = 0;
577 float gyroRate = 0;
579 applyItermRelax(FD_PITCH, 0, gyroRate, &itermErrorRate, &currentPidSetpoint);
580 EXPECT_FLOAT_EQ(itermErrorRate, 0);
581 itermErrorRate = -10;
582 currentPidSetpoint = 10;
583 pidData[FD_PITCH].I = 10;
585 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
587 EXPECT_NEAR(-8.16, itermErrorRate, calculateTolerance(-8.16));
588 currentPidSetpoint += ITERM_RELAX_SETPOINT_THRESHOLD;
589 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
590 EXPECT_NEAR(0, itermErrorRate, calculateTolerance(0));
591 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
592 EXPECT_NEAR(0, itermErrorRate, calculateTolerance(0));
594 pidProfile->iterm_relax_type = ITERM_RELAX_GYRO;
595 pidInit(pidProfile);
597 currentPidSetpoint = 100;
598 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
599 EXPECT_FLOAT_EQ(itermErrorRate, 0);
600 gyroRate = 10;
601 itermErrorRate = -10;
602 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
603 EXPECT_NEAR(7, itermErrorRate, calculateTolerance(7));
604 gyroRate += 100;
605 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
606 EXPECT_NEAR(-10, itermErrorRate, calculateTolerance(-10));
608 pidProfile->iterm_relax = ITERM_RELAX_RP_INC;
609 pidInit(pidProfile);
611 itermErrorRate = -10;
612 pidData[FD_PITCH].I = 10;
613 currentPidSetpoint = 10;
614 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
615 EXPECT_FLOAT_EQ(itermErrorRate, -10);
616 itermErrorRate = 10;
617 pidData[FD_PITCH].I = -10;
618 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
619 EXPECT_FLOAT_EQ(itermErrorRate, 10);
620 itermErrorRate = -10;
621 currentPidSetpoint = 10;
622 applyItermRelax(FD_PITCH, pidData[FD_PITCH].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
623 EXPECT_FLOAT_EQ(itermErrorRate, -100);
625 pidProfile->iterm_relax_type = ITERM_RELAX_SETPOINT;
626 pidInit(pidProfile);
628 itermErrorRate = -10;
629 currentPidSetpoint = ITERM_RELAX_SETPOINT_THRESHOLD;
630 applyItermRelax(FD_YAW, pidData[FD_YAW].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
631 EXPECT_FLOAT_EQ(itermErrorRate, -10);
633 pidProfile->iterm_relax = ITERM_RELAX_RPY;
634 pidInit(pidProfile);
635 applyItermRelax(FD_YAW, pidData[FD_YAW].I, gyroRate, &itermErrorRate, &currentPidSetpoint);
636 EXPECT_NEAR(-3.6, itermErrorRate, calculateTolerance(-3.6));
639 // TODO - Add more tests
640 TEST(pidControllerTest, testAbsoluteControl) {
641 resetTest();
642 pidProfile->abs_control_gain = 10;
643 pidInit(pidProfile);
644 ENABLE_ARMING_FLAG(ARMED);
645 pidStabilisationState(PID_STABILISATION_ON);
647 float gyroRate = 0;
649 float itermErrorRate = 10;
650 float currentPidSetpoint = 10;
652 applyAbsoluteControl(FD_PITCH, gyroRate, &currentPidSetpoint, &itermErrorRate);
654 EXPECT_NEAR(10.8, itermErrorRate, calculateTolerance(10.8));
655 EXPECT_NEAR(10.8, currentPidSetpoint, calculateTolerance(10.8));
657 applyAbsoluteControl(FD_PITCH, gyroRate, &currentPidSetpoint, &itermErrorRate);
658 EXPECT_NEAR(10.8, itermErrorRate, calculateTolerance(10.8));
659 EXPECT_NEAR(10.8, currentPidSetpoint, calculateTolerance(10.8));
661 gyroRate = -53;
662 axisError[FD_PITCH] = -60;
663 applyAbsoluteControl(FD_PITCH, gyroRate, &currentPidSetpoint, &itermErrorRate);
664 EXPECT_NEAR(-79.2, itermErrorRate, calculateTolerance(-79.2));
665 EXPECT_NEAR(-79.2, currentPidSetpoint, calculateTolerance(-79.2));
668 TEST(pidControllerTest, testDtermFiltering) {
669 // TODO
672 TEST(pidControllerTest, testItermRotationHandling) {
673 resetTest();
674 pidInit(pidProfile);
676 rotateItermAndAxisError();
677 EXPECT_FLOAT_EQ(pidData[FD_ROLL].I, 0);
678 EXPECT_FLOAT_EQ(pidData[FD_PITCH].I, 0);
679 EXPECT_FLOAT_EQ(pidData[FD_YAW].I, 0);
681 pidProfile->iterm_rotation = true;
682 pidInit(pidProfile);
684 rotateItermAndAxisError();
685 EXPECT_FLOAT_EQ(pidData[FD_ROLL].I, 0);
686 EXPECT_FLOAT_EQ(pidData[FD_PITCH].I, 0);
687 EXPECT_FLOAT_EQ(pidData[FD_YAW].I, 0);
689 pidData[FD_ROLL].I = 10;
690 pidData[FD_PITCH].I = 1000;
691 pidData[FD_YAW].I = 1000;
692 gyro.gyroADCf[FD_ROLL] = -1000;
693 rotateItermAndAxisError();
694 EXPECT_FLOAT_EQ(pidData[FD_ROLL].I, 10);
695 EXPECT_NEAR(860.37, pidData[FD_PITCH].I, calculateTolerance(860.37));
696 EXPECT_NEAR(1139.6, pidData[FD_YAW].I, calculateTolerance(1139.6));
698 pidProfile->abs_control_gain = 10;
699 pidInit(pidProfile);
700 pidData[FD_ROLL].I = 10;
701 pidData[FD_PITCH].I = 1000;
702 pidData[FD_YAW].I = 1000;
704 gyro.gyroADCf[FD_ROLL] = -1000;
705 // FIXME - axisError changes don't affect the system. This is a potential bug or intendend behaviour?
706 axisError[FD_PITCH] = 1000;
707 axisError[FD_YAW] = 1000;
708 rotateItermAndAxisError();
709 EXPECT_FLOAT_EQ(pidData[FD_ROLL].I, 10);
710 EXPECT_NEAR(860.37, pidData[FD_PITCH].I, calculateTolerance(860.37));
711 EXPECT_NEAR(1139.6, pidData[FD_YAW].I, calculateTolerance(1139.6));
714 TEST(pidControllerTest, testLaunchControl) {
715 // The launchControlGain is indirectly tested since when launch control is active the
716 // the gain overrides the PID settings. If the logic to use launchControlGain wasn't
717 // working then any I calculations would be incorrect.
719 resetTest();
720 unitLaunchControlActive = true;
721 ENABLE_ARMING_FLAG(ARMED);
722 pidStabilisationState(PID_STABILISATION_ON);
724 // test that feedforward and D are disabled (always zero) when launch control is active
725 // set initial state
726 pidController(pidProfile, currentTestTime());
728 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].F);
729 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].F);
730 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].F);
731 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
732 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
733 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
735 // Move the sticks to induce feedforward
736 setStickPosition(FD_ROLL, 0.5f);
737 setStickPosition(FD_PITCH, -0.5f);
738 setStickPosition(FD_YAW, -0.5f);
740 // add gyro activity to induce D
741 gyro.gyroADCf[FD_ROLL] = -1000;
742 gyro.gyroADCf[FD_PITCH] = 1000;
743 gyro.gyroADCf[FD_YAW] = -1000;
745 pidController(pidProfile, currentTestTime());
747 // validate that feedforwad is still 0
748 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].F);
749 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].F);
750 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].F);
752 // validate that D is still 0
753 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].D);
754 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].D);
755 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].D);
757 // test NORMAL mode - expect P/I on roll and pitch, P on yaw but I == 0
758 unitLaunchControlMode = LAUNCH_CONTROL_MODE_NORMAL;
759 resetTest();
760 unitLaunchControlActive = true;
761 ENABLE_ARMING_FLAG(ARMED);
762 pidStabilisationState(PID_STABILISATION_ON);
764 pidController(pidProfile, currentTestTime());
766 gyro.gyroADCf[FD_ROLL] = -20;
767 gyro.gyroADCf[FD_PITCH] = 20;
768 gyro.gyroADCf[FD_YAW] = -20;
769 pidController(pidProfile, currentTestTime());
771 EXPECT_NEAR(25.62, pidData[FD_ROLL].P, calculateTolerance(25.62));
772 EXPECT_NEAR(1.56, pidData[FD_ROLL].I, calculateTolerance(1.56));
773 EXPECT_NEAR(-37.15, pidData[FD_PITCH].P, calculateTolerance(-37.15));
774 EXPECT_NEAR(-1.56, pidData[FD_PITCH].I, calculateTolerance(-1.56));
775 EXPECT_NEAR(44.84, pidData[FD_YAW].P, calculateTolerance(44.84));
776 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
778 // test PITCHONLY mode - expect P/I only on pitch; I cannot go negative
779 unitLaunchControlMode = LAUNCH_CONTROL_MODE_PITCHONLY;
780 resetTest();
781 unitLaunchControlActive = true;
782 ENABLE_ARMING_FLAG(ARMED);
783 pidStabilisationState(PID_STABILISATION_ON);
785 pidController(pidProfile, currentTestTime());
787 // first test that pitch I is prevented from going negative
788 gyro.gyroADCf[FD_ROLL] = 0;
789 gyro.gyroADCf[FD_PITCH] = 20;
790 gyro.gyroADCf[FD_YAW] = 0;
791 pidController(pidProfile, currentTestTime());
793 EXPECT_FLOAT_EQ(0, pidData[FD_PITCH].I);
795 gyro.gyroADCf[FD_ROLL] = 20;
796 gyro.gyroADCf[FD_PITCH] = -20;
797 gyro.gyroADCf[FD_YAW] = 20;
798 pidController(pidProfile, currentTestTime());
800 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].P);
801 EXPECT_FLOAT_EQ(0, pidData[FD_ROLL].I);
802 EXPECT_NEAR(37.15, pidData[FD_PITCH].P, calculateTolerance(37.15));
803 EXPECT_NEAR(1.56, pidData[FD_PITCH].I, calculateTolerance(1.56));
804 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].P);
805 EXPECT_FLOAT_EQ(0, pidData[FD_YAW].I);
807 // test FULL mode - expect P/I on all axes
808 unitLaunchControlMode = LAUNCH_CONTROL_MODE_FULL;
809 resetTest();
810 unitLaunchControlActive = true;
811 ENABLE_ARMING_FLAG(ARMED);
812 pidStabilisationState(PID_STABILISATION_ON);
814 pidController(pidProfile, currentTestTime());
816 gyro.gyroADCf[FD_ROLL] = -20;
817 gyro.gyroADCf[FD_PITCH] = 20;
818 gyro.gyroADCf[FD_YAW] = -20;
819 pidController(pidProfile, currentTestTime());
821 EXPECT_NEAR(25.62, pidData[FD_ROLL].P, calculateTolerance(25.62));
822 EXPECT_NEAR(1.56, pidData[FD_ROLL].I, calculateTolerance(1.56));
823 EXPECT_NEAR(-37.15, pidData[FD_PITCH].P, calculateTolerance(-37.15));
824 EXPECT_NEAR(-1.56, pidData[FD_PITCH].I, calculateTolerance(-1.56));
825 EXPECT_NEAR(44.84, pidData[FD_YAW].P, calculateTolerance(44.84));
826 EXPECT_NEAR(1.56, pidData[FD_YAW].I, calculateTolerance(1.56));