gtsam/slam/Simulated3D.cpp

/**
* @file   Simulated3D.cpp
* @brief  measurement functions and derivatives for simulated 3D robot
* @author Alex Cunningham
**/

#include "Simulated3D.h"

namespace gtsam {
namespace simulated3D {

Vector prior (const Vector& x)
{
	return x;
}

Matrix Dprior(const Vector& x)
{
	Matrix H = eye((int) x.size());
	return H;
}

Vector odo(const Vector& x1, const Vector& x2)
{
	return x2 - x1;
}

Matrix Dodo1(const Vector& x1, const Vector& x2)
{
	Matrix H = -1 * eye((int) x1.size());
	return H;
}

Matrix Dodo2(const Vector& x1, const Vector& x2)
{
	Matrix H = eye((int) x1.size());
	return H;
}


Vector mea(const Vector& x,  const Vector& l)
{
	return l - x;
}

Matrix Dmea1(const Vector& x, const Vector& l)
{
	Matrix H = -1 * eye((int) x.size());
	return H;
}

Matrix Dmea2(const Vector& x, const Vector& l)
{
	Matrix H = eye((int) x.size());
	return H;
}

}} // namespace gtsam::simulated3D
Fixing directory structure 2009-08-22 06:23:24 +08:00			`/**`
			`* @file Simulated3D.cpp`
			`* @brief measurement functions and derivatives for simulated 3D robot`
			`* @author Alex Cunningham`
			`**/`

			`#include "Simulated3D.h"`

NOISE MODEL. This is a big edit but with no templates involed, so it should not be a big deal. New namespace gtsam::noiseModel collects all noise models, which provide efficient whitening and chain-rule implementation needed for optimization. The class hierarchy gives us the ability to use models from full covariances to i.i.d. unit variance noise with a single interface, where the latter will be much cheaper. From now on, all non-linear factors take a shared_ptr to a Gaussian noise model. This is done through the parameter (const sharedGaussian& model). The use of a shared pointer allows us to share one noise models for thousands of factors, if applicable. Just like Richard's Symbol change, there is a compile flag GTSAM_MAGIC_GAUSSIAN which allows you to use doubles, vectors, or matrices to created noise models on the fly. You have to set it to the correct dimension. Use of this is not encouraged and the flag will disappear after some good soul fixed all unit tests. 2010-01-18 13:38:53 +08:00			`namespace gtsam {`
Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`namespace simulated3D {`
Fixing directory structure 2009-08-22 06:23:24 +08:00
Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Vector prior (const Vector& x)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`return x;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Matrix Dprior(const Vector& x)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`Matrix H = eye((int) x.size());`
			`return H;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Vector odo(const Vector& x1, const Vector& x2)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`return x2 - x1;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Matrix Dodo1(const Vector& x1, const Vector& x2)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`Matrix H = -1 * eye((int) x1.size());`
			`return H;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Matrix Dodo2(const Vector& x1, const Vector& x2)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`Matrix H = eye((int) x1.size());`
			`return H;`
			`}`


Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Vector mea(const Vector& x, const Vector& l)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`return l - x;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Matrix Dmea1(const Vector& x, const Vector& l)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`Matrix H = -1 * eye((int) x.size());`
			`return H;`
			`}`

Large gtsam refactoring To support faster development and better performance Richard and I pushed through a large refactoring of NonlinearFactors. The following are the biggest changes: 1) NonLinearFactor1 and NonLinearFactor2 are now templated on Config, Key type, and X type, where X is the argument to the measurement function. 2) The measurement itself is no longer kept in the nonlinear factor. Instead, a derived class (see testVSLAMFactor, testNonlinearEquality, testPose3Factor etc...) has to implement a function to compute the errors, "evaluateErrors". Instead of (h(x)-z), it needs to return (z-h(x)), so Ax-b is an approximation of the error. IMPORTANT: evaluateErrors needs - if asked - combine the calculation of the function value h(x) and the derivatives dh(x)/dx. This was a major performance issue. To do this, boost::optional<Matrix&> arguments are provided, and tin EvaluateErrors you just says something like if (H) *H = Matrix_(3,6,....); 3) We are no longer using int or strings for nonlinear factors. Instead, the preferred key type is now Symbol, defined in Key.h. This is both fast and cool: you can construct it from an int, and cast it to a strong. It also does type checking: a Symbol<Pose3,'x'> will not match a Symbol<Pose2,'x'> 4) minor: take a look at LieConfig.h: it help you avoid writing a lot of code bu automatically creating configs for a certain type. See e.g. Pose3Config.h. A "double" LieConfig is on the way - Thanks Richard and Manohar ! 2010-01-14 06:25:03 +08:00			`Matrix Dmea2(const Vector& x, const Vector& l)`
Fixing directory structure 2009-08-22 06:23:24 +08:00			`{`
			`Matrix H = eye((int) x.size());`
			`return H;`
			`}`

NOISE MODEL. This is a big edit but with no templates involed, so it should not be a big deal. New namespace gtsam::noiseModel collects all noise models, which provide efficient whitening and chain-rule implementation needed for optimization. The class hierarchy gives us the ability to use models from full covariances to i.i.d. unit variance noise with a single interface, where the latter will be much cheaper. From now on, all non-linear factors take a shared_ptr to a Gaussian noise model. This is done through the parameter (const sharedGaussian& model). The use of a shared pointer allows us to share one noise models for thousands of factors, if applicable. Just like Richard's Symbol change, there is a compile flag GTSAM_MAGIC_GAUSSIAN which allows you to use doubles, vectors, or matrices to created noise models on the fly. You have to set it to the correct dimension. Use of this is not encouraged and the flag will disappear after some good soul fixed all unit tests. 2010-01-18 13:38:53 +08:00			`}} // namespace gtsam::simulated3D`