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source: code/branches/physics/src/bullet/BulletDynamics/ConstraintSolver/btContactConstraint.cpp @ 1963

Last change on this file since 1963 was 1963, checked in by rgrieder, 16 years ago
Added Bullet physics engine.
Property svn:eol-style set to `native`
File size: 14.0 KB

Line
1	/*
2	Bullet Continuous Collision Detection and Physics Library
3	Copyright (c) 2003-2006 Erwin Coumans http://continuousphysics.com/Bullet/
4
5	This software is provided 'as-is', without any express or implied warranty.
6	In no event will the authors be held liable for any damages arising from the use of this software.
7	Permission is granted to anyone to use this software for any purpose,
8	including commercial applications, and to alter it and redistribute it freely,
9	subject to the following restrictions:
10
11	1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required.
12	2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software.
13	3. This notice may not be removed or altered from any source distribution.
14	*/
15
16
17	#include "btContactConstraint.h"
18	#include "BulletDynamics/Dynamics/btRigidBody.h"
19	#include "LinearMath/btVector3.h"
20	#include "btJacobianEntry.h"
21	#include "btContactSolverInfo.h"
22	#include "LinearMath/btMinMax.h"
23	#include "BulletCollision/NarrowPhaseCollision/btManifoldPoint.h"
24
25	#define ASSERT2 assert
26
27	#define USE_INTERNAL_APPLY_IMPULSE 1
28
29
30	//bilateral constraint between two dynamic objects
31	void resolveSingleBilateral(btRigidBody& body1, const btVector3& pos1,
32	btRigidBody& body2, const btVector3& pos2,
33	btScalar distance, const btVector3& normal,btScalar& impulse ,btScalar timeStep)
34	{
35	(void)timeStep;
36	(void)distance;
37
38
39	btScalar normalLenSqr = normal.length2();
40	ASSERT2(btFabs(normalLenSqr) < btScalar(1.1));
41	if (normalLenSqr > btScalar(1.1))
42	{
43	impulse = btScalar(0.);
44	return;
45	}
46	btVector3 rel_pos1 = pos1 - body1.getCenterOfMassPosition();
47	btVector3 rel_pos2 = pos2 - body2.getCenterOfMassPosition();
48	//this jacobian entry could be re-used for all iterations
49
50	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
51	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
52	btVector3 vel = vel1 - vel2;
53
54
55	btJacobianEntry jac(body1.getCenterOfMassTransform().getBasis().transpose(),
56	body2.getCenterOfMassTransform().getBasis().transpose(),
57	rel_pos1,rel_pos2,normal,body1.getInvInertiaDiagLocal(),body1.getInvMass(),
58	body2.getInvInertiaDiagLocal(),body2.getInvMass());
59
60	btScalar jacDiagAB = jac.getDiagonal();
61	btScalar jacDiagABInv = btScalar(1.) / jacDiagAB;
62
63	btScalar rel_vel = jac.getRelativeVelocity(
64	body1.getLinearVelocity(),
65	body1.getCenterOfMassTransform().getBasis().transpose() * body1.getAngularVelocity(),
66	body2.getLinearVelocity(),
67	body2.getCenterOfMassTransform().getBasis().transpose() * body2.getAngularVelocity());
68	btScalar a;
69	a=jacDiagABInv;
70
71
72	rel_vel = normal.dot(vel);
73
74	//todo: move this into proper structure
75	btScalar contactDamping = btScalar(0.2);
76
77	#ifdef ONLY_USE_LINEAR_MASS
78	btScalar massTerm = btScalar(1.) / (body1.getInvMass() + body2.getInvMass());
79	impulse = - contactDamping * rel_vel * massTerm;
80	#else
81	btScalar velocityImpulse = -contactDamping * rel_vel * jacDiagABInv;
82	impulse = velocityImpulse;
83	#endif
84	}
85
86
87
88	//response between two dynamic objects with friction
89	btScalar resolveSingleCollision(
90	btRigidBody& body1,
91	btRigidBody& body2,
92	btManifoldPoint& contactPoint,
93	const btContactSolverInfo& solverInfo)
94	{
95
96	const btVector3& pos1_ = contactPoint.getPositionWorldOnA();
97	const btVector3& pos2_ = contactPoint.getPositionWorldOnB();
98	const btVector3& normal = contactPoint.m_normalWorldOnB;
99
100	//constant over all iterations
101	btVector3 rel_pos1 = pos1_ - body1.getCenterOfMassPosition();
102	btVector3 rel_pos2 = pos2_ - body2.getCenterOfMassPosition();
103
104	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
105	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
106	btVector3 vel = vel1 - vel2;
107	btScalar rel_vel;
108	rel_vel = normal.dot(vel);
109
110	btScalar Kfps = btScalar(1.) / solverInfo.m_timeStep ;
111
112	// btScalar damping = solverInfo.m_damping ;
113	btScalar Kerp = solverInfo.m_erp;
114	btScalar Kcor = Kerp *Kfps;
115
116	btConstraintPersistentData* cpd = (btConstraintPersistentData*) contactPoint.m_userPersistentData;
117	assert(cpd);
118	btScalar distance = cpd->m_penetration;
119	btScalar positionalError = Kcor *-distance;
120	btScalar velocityError = cpd->m_restitution - rel_vel;// * damping;
121
122	btScalar penetrationImpulse = positionalError * cpd->m_jacDiagABInv;
123
124	btScalar velocityImpulse = velocityError * cpd->m_jacDiagABInv;
125
126	btScalar normalImpulse = penetrationImpulse+velocityImpulse;
127
128	// See Erin Catto's GDC 2006 paper: Clamp the accumulated impulse
129	btScalar oldNormalImpulse = cpd->m_appliedImpulse;
130	btScalar sum = oldNormalImpulse + normalImpulse;
131	cpd->m_appliedImpulse = btScalar(0.) > sum ? btScalar(0.): sum;
132
133	normalImpulse = cpd->m_appliedImpulse - oldNormalImpulse;
134
135	#ifdef USE_INTERNAL_APPLY_IMPULSE
136	if (body1.getInvMass())
137	{
138	body1.internalApplyImpulse(contactPoint.m_normalWorldOnB*body1.getInvMass(),cpd->m_angularComponentA,normalImpulse);
139	}
140	if (body2.getInvMass())
141	{
142	body2.internalApplyImpulse(contactPoint.m_normalWorldOnB*body2.getInvMass(),cpd->m_angularComponentB,-normalImpulse);
143	}
144	#else //USE_INTERNAL_APPLY_IMPULSE
145	body1.applyImpulse(normal*(normalImpulse), rel_pos1);
146	body2.applyImpulse(-normal*(normalImpulse), rel_pos2);
147	#endif //USE_INTERNAL_APPLY_IMPULSE
148
149	return normalImpulse;
150	}
151
152
153	btScalar resolveSingleFriction(
154	btRigidBody& body1,
155	btRigidBody& body2,
156	btManifoldPoint& contactPoint,
157	const btContactSolverInfo& solverInfo)
158	{
159
160	(void)solverInfo;
161
162	const btVector3& pos1 = contactPoint.getPositionWorldOnA();
163	const btVector3& pos2 = contactPoint.getPositionWorldOnB();
164
165	btVector3 rel_pos1 = pos1 - body1.getCenterOfMassPosition();
166	btVector3 rel_pos2 = pos2 - body2.getCenterOfMassPosition();
167
168	btConstraintPersistentData* cpd = (btConstraintPersistentData*) contactPoint.m_userPersistentData;
169	assert(cpd);
170
171	btScalar combinedFriction = cpd->m_friction;
172
173	btScalar limit = cpd->m_appliedImpulse * combinedFriction;
174
175	if (cpd->m_appliedImpulse>btScalar(0.))
176	//friction
177	{
178	//apply friction in the 2 tangential directions
179
180	// 1st tangent
181	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
182	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
183	btVector3 vel = vel1 - vel2;
184
185	btScalar j1,j2;
186
187	{
188
189	btScalar vrel = cpd->m_frictionWorldTangential0.dot(vel);
190
191	// calculate j that moves us to zero relative velocity
192	j1 = -vrel * cpd->m_jacDiagABInvTangent0;
193	btScalar oldTangentImpulse = cpd->m_accumulatedTangentImpulse0;
194	cpd->m_accumulatedTangentImpulse0 = oldTangentImpulse + j1;
195	btSetMin(cpd->m_accumulatedTangentImpulse0, limit);
196	btSetMax(cpd->m_accumulatedTangentImpulse0, -limit);
197	j1 = cpd->m_accumulatedTangentImpulse0 - oldTangentImpulse;
198
199	}
200	{
201	// 2nd tangent
202
203	btScalar vrel = cpd->m_frictionWorldTangential1.dot(vel);
204
205	// calculate j that moves us to zero relative velocity
206	j2 = -vrel * cpd->m_jacDiagABInvTangent1;
207	btScalar oldTangentImpulse = cpd->m_accumulatedTangentImpulse1;
208	cpd->m_accumulatedTangentImpulse1 = oldTangentImpulse + j2;
209	btSetMin(cpd->m_accumulatedTangentImpulse1, limit);
210	btSetMax(cpd->m_accumulatedTangentImpulse1, -limit);
211	j2 = cpd->m_accumulatedTangentImpulse1 - oldTangentImpulse;
212	}
213
214	#ifdef USE_INTERNAL_APPLY_IMPULSE
215	if (body1.getInvMass())
216	{
217	body1.internalApplyImpulse(cpd->m_frictionWorldTangential0*body1.getInvMass(),cpd->m_frictionAngularComponent0A,j1);
218	body1.internalApplyImpulse(cpd->m_frictionWorldTangential1*body1.getInvMass(),cpd->m_frictionAngularComponent1A,j2);
219	}
220	if (body2.getInvMass())
221	{
222	body2.internalApplyImpulse(cpd->m_frictionWorldTangential0*body2.getInvMass(),cpd->m_frictionAngularComponent0B,-j1);
223	body2.internalApplyImpulse(cpd->m_frictionWorldTangential1*body2.getInvMass(),cpd->m_frictionAngularComponent1B,-j2);
224	}
225	#else //USE_INTERNAL_APPLY_IMPULSE
226	body1.applyImpulse((j1 * cpd->m_frictionWorldTangential0)+(j2 * cpd->m_frictionWorldTangential1), rel_pos1);
227	body2.applyImpulse((j1 * -cpd->m_frictionWorldTangential0)+(j2 * -cpd->m_frictionWorldTangential1), rel_pos2);
228	#endif //USE_INTERNAL_APPLY_IMPULSE
229
230
231	}
232	return cpd->m_appliedImpulse;
233	}
234
235
236	btScalar resolveSingleFrictionOriginal(
237	btRigidBody& body1,
238	btRigidBody& body2,
239	btManifoldPoint& contactPoint,
240	const btContactSolverInfo& solverInfo);
241
242	btScalar resolveSingleFrictionOriginal(
243	btRigidBody& body1,
244	btRigidBody& body2,
245	btManifoldPoint& contactPoint,
246	const btContactSolverInfo& solverInfo)
247	{
248
249	(void)solverInfo;
250
251	const btVector3& pos1 = contactPoint.getPositionWorldOnA();
252	const btVector3& pos2 = contactPoint.getPositionWorldOnB();
253
254	btVector3 rel_pos1 = pos1 - body1.getCenterOfMassPosition();
255	btVector3 rel_pos2 = pos2 - body2.getCenterOfMassPosition();
256
257	btConstraintPersistentData* cpd = (btConstraintPersistentData*) contactPoint.m_userPersistentData;
258	assert(cpd);
259
260	btScalar combinedFriction = cpd->m_friction;
261
262	btScalar limit = cpd->m_appliedImpulse * combinedFriction;
263	//if (contactPoint.m_appliedImpulse>btScalar(0.))
264	//friction
265	{
266	//apply friction in the 2 tangential directions
267
268	{
269	// 1st tangent
270	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
271	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
272	btVector3 vel = vel1 - vel2;
273
274	btScalar vrel = cpd->m_frictionWorldTangential0.dot(vel);
275
276	// calculate j that moves us to zero relative velocity
277	btScalar j = -vrel * cpd->m_jacDiagABInvTangent0;
278	btScalar total = cpd->m_accumulatedTangentImpulse0 + j;
279	btSetMin(total, limit);
280	btSetMax(total, -limit);
281	j = total - cpd->m_accumulatedTangentImpulse0;
282	cpd->m_accumulatedTangentImpulse0 = total;
283	body1.applyImpulse(j * cpd->m_frictionWorldTangential0, rel_pos1);
284	body2.applyImpulse(j * -cpd->m_frictionWorldTangential0, rel_pos2);
285	}
286
287
288	{
289	// 2nd tangent
290	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
291	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
292	btVector3 vel = vel1 - vel2;
293
294	btScalar vrel = cpd->m_frictionWorldTangential1.dot(vel);
295
296	// calculate j that moves us to zero relative velocity
297	btScalar j = -vrel * cpd->m_jacDiagABInvTangent1;
298	btScalar total = cpd->m_accumulatedTangentImpulse1 + j;
299	btSetMin(total, limit);
300	btSetMax(total, -limit);
301	j = total - cpd->m_accumulatedTangentImpulse1;
302	cpd->m_accumulatedTangentImpulse1 = total;
303	body1.applyImpulse(j * cpd->m_frictionWorldTangential1, rel_pos1);
304	body2.applyImpulse(j * -cpd->m_frictionWorldTangential1, rel_pos2);
305	}
306	}
307	return cpd->m_appliedImpulse;
308	}
309
310
311	//velocity + friction
312	//response between two dynamic objects with friction
313	btScalar resolveSingleCollisionCombined(
314	btRigidBody& body1,
315	btRigidBody& body2,
316	btManifoldPoint& contactPoint,
317	const btContactSolverInfo& solverInfo)
318	{
319
320	const btVector3& pos1 = contactPoint.getPositionWorldOnA();
321	const btVector3& pos2 = contactPoint.getPositionWorldOnB();
322	const btVector3& normal = contactPoint.m_normalWorldOnB;
323
324	btVector3 rel_pos1 = pos1 - body1.getCenterOfMassPosition();
325	btVector3 rel_pos2 = pos2 - body2.getCenterOfMassPosition();
326
327	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
328	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
329	btVector3 vel = vel1 - vel2;
330	btScalar rel_vel;
331	rel_vel = normal.dot(vel);
332
333	btScalar Kfps = btScalar(1.) / solverInfo.m_timeStep ;
334
335	//btScalar damping = solverInfo.m_damping ;
336	btScalar Kerp = solverInfo.m_erp;
337	btScalar Kcor = Kerp *Kfps;
338
339	btConstraintPersistentData* cpd = (btConstraintPersistentData*) contactPoint.m_userPersistentData;
340	assert(cpd);
341	btScalar distance = cpd->m_penetration;
342	btScalar positionalError = Kcor *-distance;
343	btScalar velocityError = cpd->m_restitution - rel_vel;// * damping;
344
345	btScalar penetrationImpulse = positionalError * cpd->m_jacDiagABInv;
346
347	btScalar velocityImpulse = velocityError * cpd->m_jacDiagABInv;
348
349	btScalar normalImpulse = penetrationImpulse+velocityImpulse;
350
351	// See Erin Catto's GDC 2006 paper: Clamp the accumulated impulse
352	btScalar oldNormalImpulse = cpd->m_appliedImpulse;
353	btScalar sum = oldNormalImpulse + normalImpulse;
354	cpd->m_appliedImpulse = btScalar(0.) > sum ? btScalar(0.): sum;
355
356	normalImpulse = cpd->m_appliedImpulse - oldNormalImpulse;
357
358
359	#ifdef USE_INTERNAL_APPLY_IMPULSE
360	if (body1.getInvMass())
361	{
362	body1.internalApplyImpulse(contactPoint.m_normalWorldOnB*body1.getInvMass(),cpd->m_angularComponentA,normalImpulse);
363	}
364	if (body2.getInvMass())
365	{
366	body2.internalApplyImpulse(contactPoint.m_normalWorldOnB*body2.getInvMass(),cpd->m_angularComponentB,-normalImpulse);
367	}
368	#else //USE_INTERNAL_APPLY_IMPULSE
369	body1.applyImpulse(normal*(normalImpulse), rel_pos1);
370	body2.applyImpulse(-normal*(normalImpulse), rel_pos2);
371	#endif //USE_INTERNAL_APPLY_IMPULSE
372
373	{
374	//friction
375	btVector3 vel1 = body1.getVelocityInLocalPoint(rel_pos1);
376	btVector3 vel2 = body2.getVelocityInLocalPoint(rel_pos2);
377	btVector3 vel = vel1 - vel2;
378
379	rel_vel = normal.dot(vel);
380
381
382	btVector3 lat_vel = vel - normal * rel_vel;
383	btScalar lat_rel_vel = lat_vel.length();
384
385	btScalar combinedFriction = cpd->m_friction;
386
387	if (cpd->m_appliedImpulse > 0)
388	if (lat_rel_vel > SIMD_EPSILON)
389	{
390	lat_vel /= lat_rel_vel;
391	btVector3 temp1 = body1.getInvInertiaTensorWorld() * rel_pos1.cross(lat_vel);
392	btVector3 temp2 = body2.getInvInertiaTensorWorld() * rel_pos2.cross(lat_vel);
393	btScalar friction_impulse = lat_rel_vel /
394	(body1.getInvMass() + body2.getInvMass() + lat_vel.dot(temp1.cross(rel_pos1) + temp2.cross(rel_pos2)));
395	btScalar normal_impulse = cpd->m_appliedImpulse * combinedFriction;
396
397	btSetMin(friction_impulse, normal_impulse);
398	btSetMax(friction_impulse, -normal_impulse);
399	body1.applyImpulse(lat_vel * -friction_impulse, rel_pos1);
400	body2.applyImpulse(lat_vel * friction_impulse, rel_pos2);
401	}
402	}
403
404
405
406	return normalImpulse;
407	}
408
409	btScalar resolveSingleFrictionEmpty(
410	btRigidBody& body1,
411	btRigidBody& body2,
412	btManifoldPoint& contactPoint,
413	const btContactSolverInfo& solverInfo);
414
415	btScalar resolveSingleFrictionEmpty(
416	btRigidBody& body1,
417	btRigidBody& body2,
418	btManifoldPoint& contactPoint,
419	const btContactSolverInfo& solverInfo)
420	{
421	(void)contactPoint;
422	(void)body1;
423	(void)body2;
424	(void)solverInfo;
425
426
427	return btScalar(0.);
428	};
429

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