Difference between revisions of "User:Dora Gustafson/llRotBetween alternatives"
Jump to navigation
Jump to search
| (7 intermediate revisions by the same user not shown) | |||
| Line 16: | Line 16: | ||
== Test with random, normalized vectors == | == Test with random, normalized vectors == | ||
< | <source lang="lsl2"> | ||
cycles = 0; | cycles = 0; | ||
record = []; | record = []; | ||
| Line 25: | Line 25: | ||
solution = rotbetween( u, v); | solution = rotbetween( u, v); | ||
if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v]; | if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v]; | ||
}</ | }</source> | ||
<table style="width: 800px;" border="1" cellpadding="2" | <table style="width: 800px;" border="1" cellpadding="2" | ||
cellspacing="2"> | cellspacing="2"> | ||
| Line 85: | Line 85: | ||
== Test with close to parallel and anti parallel vectors == | == Test with close to parallel and anti parallel vectors == | ||
< | <source lang="lsl2"> | ||
cycles = 0; | cycles = 0; | ||
record = []; | record = []; | ||
| Line 96: | Line 96: | ||
solution = rotbetween( u, v); | solution = rotbetween( u, v); | ||
if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v]; | if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v]; | ||
}</ | }</source> | ||
<table style="width: 800px;" border="1" cellpadding="2" | <table style="width: 800px;" border="1" cellpadding="2" | ||
cellspacing="2"> | cellspacing="2"> | ||
| Line 156: | Line 156: | ||
: The rotation will point a vector in the right direction, i.e. the rotation's ''forward'' is the vector direction. | : The rotation will point a vector in the right direction, i.e. the rotation's ''forward'' is the vector direction. | ||
: See [[User:Dora_Gustafson/llRotBetween_alternatives#About_the_function.27s_nature|note]] about the functions nature | : See [[User:Dora_Gustafson/llRotBetween_alternatives#About_the_function.27s_nature|note]] about the functions nature | ||
: Function 4 is different, | : Function 4 is different, the solution will map a rotation with ''left'' in the horizontal plane | ||
== Scripts and functions == | == Scripts and functions == | ||
;Function 1, llRotBetween( vector a, vector b) | ;Function 1, llRotBetween( vector a, vector b) | ||
: This is the built in function, see [[LlRotBetween|llRotBetween]] | : This is the built in function, see [[LlRotBetween|llRotBetween]] | ||
: See [[Dora_Gustafson/llRotBetween_alternatives | : See [[User:Dora_Gustafson/llRotBetween_alternatives#About_the_function.27s_nature|note]] about the functions nature | ||
;Function 2, RotBetween( vector a, vector b) | ;Function 2, RotBetween( vector a, vector b) | ||
: This is the suggested [[LlRotBetween#Replacement|Replacement]] for llRotBetween | : This is the suggested [[LlRotBetween#Replacement|Replacement]] for llRotBetween | ||
: See [[Dora_Gustafson/llRotBetween_alternatives | : See [[User:Dora_Gustafson/llRotBetween_alternatives#About_the_function.27s_nature|note]] about the functions nature | ||
;Function 3, rotV2V( vector a, vector b) | ;Function 3, rotV2V( vector a, vector b) | ||
< | <source lang="lsl2">rotation rotV2V( vector a, vector b) | ||
{ | { | ||
a = llVecNorm(a); | a = llVecNorm(a); | ||
| Line 175: | Line 175: | ||
return ZERO_ROTATION/llAxes2Rot( a, c, a%c)*llAxes2Rot( b, c, b%c); | return ZERO_ROTATION/llAxes2Rot( a, c, a%c)*llAxes2Rot( b, c, b%c); | ||
} | } | ||
</ | </source> | ||
: See [[Dora_Gustafson/llRotBetween_alternatives | : See [[User:Dora_Gustafson/llRotBetween_alternatives#About_the_function.27s_nature|note]] about the functions nature | ||
;Function 4, rotbetween( vector a, vector b) | ;Function 4, rotbetween( vector a, vector b) | ||
< | <source lang="lsl2">rotation Vec2Rot( vector a) | ||
{ | { | ||
a = llVecNorm(a); | a = llVecNorm(a); | ||
| Line 192: | Line 192: | ||
return ZERO_ROTATION/Vec2Rot(a)*Vec2Rot(b); | return ZERO_ROTATION/Vec2Rot(a)*Vec2Rot(b); | ||
} | } | ||
</ | </source> | ||
: Returns a rotation with ''left'' in the horizontal plane. This is convenient for cameras and prims you don't want tilted | : Returns a solution that will map a rotation with ''left'' in the horizontal plane. This is convenient for cameras and prims you don't want tilted | ||
---- | ---- | ||
==About the function's nature== | ==About the function's nature== | ||
The function determines a rotation (quaternion) which can map a vector onto another. | The function determines a rotation (quaternion) which can map a vector onto another. | ||
: It does nothing else, which means that there are no conditions on the other vectors associated with a rotation in space. | : It does nothing else, which means that there are no conditions on the other vectors associated with a rotation in space. | ||
When the solution is used to rotate a body in space one should be aware of it’s nature. | When the solution is used to rotate a body in space one should be aware of it’s nature. | ||
: For a prim whose | : For a prim whose rotation is defined by three orthogonal vectors the forward vector mapping will be correct while the other vector mappings are unpredictable. | ||
A prim mapping will normally be rotated about the prim’s forward axis in an unpredictable way. | : A prim mapping will normally be rotated about the prim’s forward axis in an unpredictable way. | ||
: The prim will be tilted to one side or the other side with respect to the vertical. | : The prim will be tilted to one side or the other side with respect to the vertical. | ||
There are numerous solutions to the task of finding the rotation between two vectors and all are correct in the sense that they can correctly map one vector onto another. | There are numerous solutions to the task of finding the rotation between two vectors and all are correct in the sense that they can correctly map one vector onto another. | ||
{{LSLC|Library}} | {{LSLC|Library}} | ||
Latest revision as of 13:46, 22 January 2015
llRotBetween, some alternatives and considerations
Scope
Four functions are covered, They are
- llRotBetween( vector a, vector b); // The built in function
- RotBetween( vector a, vector b); // The replacement outlined in the wiki
- rotV2V( vector a, vector b); // The shortest replacement
- rotbetween( vector a, vector b); // Using a Vector to rotation function
Tests
First the rotations provided by functions were compared and they didn't compare at all.
- Testing rotations is a bad idea since there is no single solution to the question, but an infinite number of solutions.
- All 4 functions provide valid, but different rotations.
So the sensible thing to do is to test how the solution rotates a vector:
Test with random, normalized vectors
cycles = 0;
record = [];
while ( cycles++ < nLimit && llGetListLength( record) < 30)
{
u = llVecNorm(< llFrand( 2.0)-1.0, llFrand( 2.0)-1.0, llFrand( 2.0)-1.0 >);
v = llVecNorm(< llFrand( 2.0)-1.0, llFrand( 2.0)-1.0, llFrand( 2.0)-1.0 >);
solution = rotbetween( u, v);
if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v];
}
| Errors / test cycles | Function 1 | Function 2 | Function 3 | Function 4 |
|---|---|---|---|---|
| llRotBetween | RotBetween | rotV2V | rotbetween | |
| abs error > 1e-7 | 10 / 13 | 10 / 18 | 10 / 15 | 10 / 16 |
| 10 / 14 | 10 / 21 | 10 / 22 | 10 / 23 | |
| 10 / 27 | 10 / 14 | 10 / 13 | ||
| abs error > 1e-6 | 7 / 1000 | 0 / 1000 | 0 / 1000 | 0 / 1000 |
| 3 / 1000 | 0 / 10000 | 1 / 10000 | 0 / 10000 | |
| 8 / 1000 | 0 / 10000 |
Test with close to parallel and anti parallel vectors
cycles = 0;
record = [];
while ( cycles++ < nLimit && llGetListLength( record) < 30)
{
u = llVecNorm(< llFrand( 2.0)-1.0, llFrand( 2.0)-1.0, llFrand( 2.0)-1.0 >);
v = < llFrand( 2E-3)-1E-3, llFrand( 2E-3)-1E-3, llFrand( 2E-3)-1E-3 >;
if ( llFrand(1.0) < 0.5 ) v -= u;
else v += u;
solution = rotbetween( u, v);
if ( llVecDist( u*solution, v) > epsilon ) record += [cycles, u, v];
}
| Errors / test cycles | Function 1 | Function 2 | Function 3 | Function 4 |
|---|---|---|---|---|
| llRotBetween | RotBetween | rotV2V | rotbetween | |
| abs error > 1e-3 | 10 / 16 | 10 / 98 | 10 / 222 | 10 / 192 |
| 10 / 15 | 10 / 96 | 10 / 89 | 10 / 164 | |
| 10 / 27 | 10 / 109 | 10 / 99 | 10 / 75 | |
| abs error > 1e-2 | 0 / 1000 | 0 / 1000 | 0 / 1000 | 0 / 1000 |
| 0 / 10000 | 0 / 10000 | 0 / 10000 | 0 / 10000 |
Conclusion
Functions 2, 3 and 4 have similar performances.
Function 1, the built-in, has a lower performance.
All four functions are very good except with parallel and anti parallel vectors.
The rotation found is not always what you expect.
- The rotation will point a vector in the right direction, i.e. the rotation's forward is the vector direction.
- See note about the functions nature
- Function 4 is different, the solution will map a rotation with left in the horizontal plane
Scripts and functions
- Function 1, llRotBetween( vector a, vector b)
- This is the built in function, see llRotBetween
- See note about the functions nature
- Function 2, RotBetween( vector a, vector b)
- This is the suggested Replacement for llRotBetween
- See note about the functions nature
- Function 3, rotV2V( vector a, vector b)
rotation rotV2V( vector a, vector b)
{
a = llVecNorm(a);
b = llVecNorm(b);
vector c = b;
while ( llFabs(a*c) > 0.999999 ) c = llVecNorm(< llFrand( 2.0)-1.0, llFrand( 2.0)-1.0, llFrand( 2.0)-1.0 >);
c = llVecNorm(a%c);
return ZERO_ROTATION/llAxes2Rot( a, c, a%c)*llAxes2Rot( b, c, b%c);
}
- See note about the functions nature
- Function 4, rotbetween( vector a, vector b)
rotation Vec2Rot( vector a)
{
a = llVecNorm(a);
vector c = < 0.0, 0.0, 1.0 >;
if ( llFabs(a*c) > 0.999999 ) c = llVecNorm(< llFrand( 2.0)-1.0, llFrand( 2.0)-1.0, 0.0 >);
vector b = llVecNorm(c%a);
return llAxes2Rot( a, b, a%b);
}
rotation rotbetween( vector a, vector b)
{
return ZERO_ROTATION/Vec2Rot(a)*Vec2Rot(b);
}
- Returns a solution that will map a rotation with left in the horizontal plane. This is convenient for cameras and prims you don't want tilted
About the function's nature
The function determines a rotation (quaternion) which can map a vector onto another.
- It does nothing else, which means that there are no conditions on the other vectors associated with a rotation in space.
When the solution is used to rotate a body in space one should be aware of it’s nature.
- For a prim whose rotation is defined by three orthogonal vectors the forward vector mapping will be correct while the other vector mappings are unpredictable.
- A prim mapping will normally be rotated about the prim’s forward axis in an unpredictable way.
- The prim will be tilted to one side or the other side with respect to the vertical.
There are numerous solutions to the task of finding the rotation between two vectors and all are correct in the sense that they can correctly map one vector onto another.