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// Ceres Solver - A fast non-linear least squares minimizer
// Copyright 2015 Google Inc. All rights reserved.
// http://ceres-solver.org/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// * Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
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// used to endorse or promote products derived from this software without
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//
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// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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//
// Author: sameeragarwal@google.com (Sameer Agarwal)
#include "ceres/corrector.h"
#include <cstddef>
#include <cmath>
#include "ceres/internal/eigen.h"
#include "glog/logging.h"
namespace ceres {
namespace internal {
Corrector::Corrector(const double sq_norm, const double rho[3]) {
CHECK_GE(sq_norm, 0.0);
sqrt_rho1_ = sqrt(rho[1]);
// If sq_norm = 0.0, the correction becomes trivial, the residual
// and the jacobian are scaled by the squareroot of the derivative
// of rho. Handling this case explicitly avoids the divide by zero
// error that would occur below.
//
// The case where rho'' < 0 also gets special handling. Technically
// it shouldn't, and the computation of the scaling should proceed
// as below, however we found in experiments that applying the
// curvature correction when rho'' < 0, which is the case when we
// are in the outlier region slows down the convergence of the
// algorithm significantly.
//
// Thus, we have divided the action of the robustifier into two
// parts. In the inliner region, we do the full second order
// correction which re-wights the gradient of the function by the
// square root of the derivative of rho, and the Gauss-Newton
// Hessian gets both the scaling and the rank-1 curvature
// correction. Normaly, alpha is upper bounded by one, but with this
// change, alpha is bounded above by zero.
//
// Empirically we have observed that the full Triggs correction and
// the clamped correction both start out as very good approximations
// to the loss function when we are in the convex part of the
// function, but as the function starts transitioning from convex to
// concave, the Triggs approximation diverges more and more and
// ultimately becomes linear. The clamped Triggs model however
// remains quadratic.
//
// The reason why the Triggs approximation becomes so poor is
// because the curvature correction that it applies to the gauss
// newton hessian goes from being a full rank correction to a rank
// deficient correction making the inversion of the Hessian fraught
// with all sorts of misery and suffering.
//
// The clamped correction retains its quadratic nature and inverting it
// is always well formed.
if ((sq_norm == 0.0) || (rho[2] <= 0.0)) {
residual_scaling_ = sqrt_rho1_;
alpha_sq_norm_ = 0.0;
return;
}
// We now require that the first derivative of the loss function be
// positive only if the second derivative is positive. This is
// because when the second derivative is non-positive, we do not use
// the second order correction suggested by BANS and instead use a
// simpler first order strategy which does not use a division by the
// gradient of the loss function.
CHECK_GT(rho[1], 0.0);
// Calculate the smaller of the two solutions to the equation
//
// 0.5 * alpha^2 - alpha - rho'' / rho' * z'z = 0.
//
// Start by calculating the discriminant D.
const double D = 1.0 + 2.0 * sq_norm * rho[2] / rho[1];
// Since both rho[1] and rho[2] are guaranteed to be positive at
// this point, we know that D > 1.0.
const double alpha = 1.0 - sqrt(D);
// Calculate the constants needed by the correction routines.
residual_scaling_ = sqrt_rho1_ / (1 - alpha);
alpha_sq_norm_ = alpha / sq_norm;
}
void Corrector::CorrectResiduals(const int num_rows, double* residuals) {
DCHECK(residuals != NULL);
// Equation 11 in BANS.
VectorRef(residuals, num_rows) *= residual_scaling_;
}
void Corrector::CorrectJacobian(const int num_rows,
const int num_cols,
double* residuals,
double* jacobian) {
DCHECK(residuals != NULL);
DCHECK(jacobian != NULL);
// The common case (rho[2] <= 0).
if (alpha_sq_norm_ == 0.0) {
VectorRef(jacobian, num_rows * num_cols) *= sqrt_rho1_;
return;
}
// Equation 11 in BANS.
//
// J = sqrt(rho) * (J - alpha^2 r * r' J)
//
// In days gone by this loop used to be a single Eigen expression of
// the form
//
// J = sqrt_rho1_ * (J - alpha_sq_norm_ * r* (r.transpose() * J));
//
// Which turns out to about 17x slower on bal problems. The reason
// is that Eigen is unable to figure out that this expression can be
// evaluated columnwise and ends up creating a temporary.
for (int c = 0; c < num_cols; ++c) {
double r_transpose_j = 0.0;
for (int r = 0; r < num_rows; ++r) {
r_transpose_j += jacobian[r * num_cols + c] * residuals[r];
}
for (int r = 0; r < num_rows; ++r) {
jacobian[r * num_cols + c] = sqrt_rho1_ *
(jacobian[r * num_cols + c] -
alpha_sq_norm_ * residuals[r] * r_transpose_j);
}
}
}
} // namespace internal
} // namespace ceres