| .. default-domain:: cpp |
| |
| .. cpp:namespace:: ceres |
| |
| .. _chapter-numerical_derivatives: |
| |
| =================== |
| Numeric derivatives |
| =================== |
| |
| The other extreme from using analytic derivatives is to use numeric |
| derivatives. The key observation here is that the process of |
| differentiating a function :math:`f(x)` w.r.t :math:`x` can be written |
| as the limiting process: |
| |
| .. math:: |
| Df(x) = \lim_{h \rightarrow 0} \frac{f(x + h) - f(x)}{h} |
| |
| |
| Forward Differences |
| =================== |
| |
| Now of course one cannot perform the limiting operation numerically on |
| a computer so we do the next best thing, which is to choose a small |
| value of :math:`h` and approximate the derivative as |
| |
| .. math:: |
| Df(x) \approx \frac{f(x + h) - f(x)}{h} |
| |
| |
| The above formula is the simplest most basic form of numeric |
| differentiation. It is known as the *Forward Difference* formula. |
| |
| So how would one go about constructing a numerically differentiated |
| version of ``Rat43Analytic`` (`Rat43 |
| <http://www.itl.nist.gov/div898/strd/nls/data/ratkowsky3.shtml>`_) in |
| Ceres Solver. This is done in two steps: |
| |
| 1. Define *Functor* that given the parameter values will evaluate the |
| residual for a given :math:`(x,y)`. |
| 2. Construct a :class:`CostFunction` by using |
| :class:`NumericDiffCostFunction` to wrap an instance of |
| ``Rat43CostFunctor``. |
| |
| .. code-block:: c++ |
| |
| struct Rat43CostFunctor { |
| Rat43CostFunctor(const double x, const double y) : x_(x), y_(y) {} |
| |
| bool operator()(const double* parameters, double* residuals) const { |
| const double b1 = parameters[0]; |
| const double b2 = parameters[1]; |
| const double b3 = parameters[2]; |
| const double b4 = parameters[3]; |
| residuals[0] = b1 * pow(1.0 + exp(b2 - b3 * x_), -1.0 / b4) - y_; |
| return true; |
| } |
| |
| const double x_; |
| const double y_; |
| } |
| |
| CostFunction* cost_function = |
| new NumericDiffCostFunction<Rat43CostFunctor, FORWARD, 1, 4>( |
| new Rat43CostFunctor(x, y)); |
| |
| This is about the minimum amount of work one can expect to do to |
| define the cost function. The only thing that the user needs to do is |
| to make sure that the evaluation of the residual is implemented |
| correctly and efficiently. |
| |
| Before going further, it is instructive to get an estimate of the |
| error in the forward difference formula. We do this by considering the |
| `Taylor expansion <https://en.wikipedia.org/wiki/Taylor_series>`_ of |
| :math:`f` near :math:`x`. |
| |
| .. math:: |
| \begin{align} |
| f(x+h) &= f(x) + h Df(x) + \frac{h^2}{2!} D^2f(x) + |
| \frac{h^3}{3!}D^3f(x) + \cdots \\ |
| Df(x) &= \frac{f(x + h) - f(x)}{h} - \left [\frac{h}{2!}D^2f(x) + |
| \frac{h^2}{3!}D^3f(x) + \cdots \right]\\ |
| Df(x) &= \frac{f(x + h) - f(x)}{h} + O(h) |
| \end{align} |
| |
| i.e., the error in the forward difference formula is |
| :math:`O(h)` [#f4]_. |
| |
| |
| Implementation Details |
| ---------------------- |
| |
| :class:`NumericDiffCostFunction` implements a generic algorithm to |
| numerically differentiate a given functor. While the actual |
| implementation of :class:`NumericDiffCostFunction` is complicated, the |
| net result is a :class:`CostFunction` that roughly looks something |
| like the following: |
| |
| .. code-block:: c++ |
| |
| class Rat43NumericDiffForward : public SizedCostFunction<1,4> { |
| public: |
| Rat43NumericDiffForward(const Rat43Functor* functor) : functor_(functor) {} |
| virtual ~Rat43NumericDiffForward() {} |
| virtual bool Evaluate(double const* const* parameters, |
| double* residuals, |
| double** jacobians) const { |
| functor_(parameters[0], residuals); |
| if (!jacobians) return true; |
| double* jacobian = jacobians[0]; |
| if (!jacobian) return true; |
| |
| const double f = residuals[0]; |
| double parameters_plus_h[4]; |
| for (int i = 0; i < 4; ++i) { |
| std::copy(parameters, parameters + 4, parameters_plus_h); |
| const double kRelativeStepSize = 1e-6; |
| const double h = std::abs(parameters[i]) * kRelativeStepSize; |
| parameters_plus_h[i] += h; |
| double f_plus; |
| functor_(parameters_plus_h, &f_plus); |
| jacobian[i] = (f_plus - f) / h; |
| } |
| return true; |
| } |
| |
| private: |
| scoped_ptr<Rat43Functor> functor_; |
| }; |
| |
| |
| Note the choice of step size :math:`h` in the above code, instead of |
| an absolute step size which is the same for all parameters, we use a |
| relative step size of :math:`\text{kRelativeStepSize} = 10^{-6}`. This |
| gives better derivative estimates than an absolute step size [#f2]_ |
| [#f3]_. This choice of step size only works for parameter values that |
| are not close to zero. So the actual implementation of |
| :class:`NumericDiffCostFunction`, uses a more complex step size |
| selection logic, where close to zero, it switches to a fixed step |
| size. |
| |
| |
| Central Differences |
| =================== |
| |
| :math:`O(h)` error in the Forward Difference formula is okay but not |
| great. A better method is to use the *Central Difference* formula: |
| |
| .. math:: |
| Df(x) \approx \frac{f(x + h) - f(x - h)}{2h} |
| |
| Notice that if the value of :math:`f(x)` is known, the Forward |
| Difference formula only requires one extra evaluation, but the Central |
| Difference formula requires two evaluations, making it twice as |
| expensive. So is the extra evaluation worth it? |
| |
| To answer this question, we again compute the error of approximation |
| in the central difference formula: |
| |
| .. math:: |
| \begin{align} |
| f(x + h) &= f(x) + h Df(x) + \frac{h^2}{2!} |
| D^2f(x) + \frac{h^3}{3!} D^3f(x) + \frac{h^4}{4!} D^4f(x) + \cdots\\ |
| f(x - h) &= f(x) - h Df(x) + \frac{h^2}{2!} |
| D^2f(x) - \frac{h^3}{3!} D^3f(c_2) + \frac{h^4}{4!} D^4f(x) + |
| \cdots\\ |
| Df(x) & = \frac{f(x + h) - f(x - h)}{2h} + \frac{h^2}{3!} |
| D^3f(x) + \frac{h^4}{5!} |
| D^5f(x) + \cdots \\ |
| Df(x) & = \frac{f(x + h) - f(x - h)}{2h} + O(h^2) |
| \end{align} |
| |
| The error of the Central Difference formula is :math:`O(h^2)`, i.e., |
| the error goes down quadratically whereas the error in the Forward |
| Difference formula only goes down linearly. |
| |
| Using central differences instead of forward differences in Ceres |
| Solver is a simple matter of changing a template argument to |
| :class:`NumericDiffCostFunction` as follows: |
| |
| .. code-block:: c++ |
| |
| CostFunction* cost_function = |
| new NumericDiffCostFunction<Rat43CostFunctor, CENTRAL, 1, 4>( |
| new Rat43CostFunctor(x, y)); |
| |
| But what do these differences in the error mean in practice? To see |
| this, consider the problem of evaluating the derivative of the |
| univariate function |
| |
| .. math:: |
| f(x) = \frac{e^x}{\sin x - x^2}, |
| |
| at :math:`x = 1.0`. |
| |
| It is easy to determine that :math:`Df(1.0) = |
| 140.73773557129658`. Using this value as reference, we can now compute |
| the relative error in the forward and central difference formulae as a |
| function of the absolute step size and plot them. |
| |
| .. figure:: forward_central_error.png |
| :figwidth: 100% |
| :align: center |
| |
| Reading the graph from right to left, a number of things stand out in |
| the above graph: |
| |
| 1. The graph for both formulae have two distinct regions. At first, |
| starting from a large value of :math:`h` the error goes down as |
| the effect of truncating the Taylor series dominates, but as the |
| value of :math:`h` continues to decrease, the error starts |
| increasing again as roundoff error starts to dominate the |
| computation. So we cannot just keep on reducing the value of |
| :math:`h` to get better estimates of :math:`Df`. The fact that we |
| are using finite precision arithmetic becomes a limiting factor. |
| 2. Forward Difference formula is not a great method for evaluating |
| derivatives. Central Difference formula converges much more |
| quickly to a more accurate estimate of the derivative with |
| decreasing step size. So unless the evaluation of :math:`f(x)` is |
| so expensive that you absolutely cannot afford the extra |
| evaluation required by central differences, **do not use the |
| Forward Difference formula**. |
| 3. Neither formula works well for a poorly chosen value of :math:`h`. |
| |
| |
| Ridders' Method |
| =============== |
| |
| So, can we get better estimates of :math:`Df` without requiring such |
| small values of :math:`h` that we start hitting floating point |
| roundoff errors? |
| |
| One possible approach is to find a method whose error goes down faster |
| than :math:`O(h^2)`. This can be done by applying `Richardson |
| Extrapolation |
| <https://en.wikipedia.org/wiki/Richardson_extrapolation>`_ to the |
| problem of differentiation. This is also known as *Ridders' Method* |
| [Ridders]_. |
| |
| Let us recall, the error in the central differences formula. |
| |
| .. math:: |
| \begin{align} |
| Df(x) & = \frac{f(x + h) - f(x - h)}{2h} + \frac{h^2}{3!} |
| D^3f(x) + \frac{h^4}{5!} |
| D^5f(x) + \cdots\\ |
| & = \frac{f(x + h) - f(x - h)}{2h} + K_2 h^2 + K_4 h^4 + \cdots |
| \end{align} |
| |
| The key thing to note here is that the terms :math:`K_2, K_4, ...` |
| are indepdendent of :math:`h` and only depend on :math:`x`. |
| |
| Let us now define: |
| |
| .. math:: |
| |
| A(1, m) = \frac{f(x + h/2^{m-1}) - f(x - h/2^{m-1})}{2h/2^{m-1}}. |
| |
| Then observe that |
| |
| .. math:: |
| |
| Df(x) = A(1,1) + K_2 h^2 + K_4 h^4 + \cdots |
| |
| and |
| |
| .. math:: |
| |
| Df(x) = A(1, 2) + K_2 (h/2)^2 + K_4 (h/2)^4 + \cdots |
| |
| Here we have halved the step size to obtain a second central |
| differences estimate of :math:`Df(x)`. Combining these two estimates, |
| we get: |
| |
| .. math:: |
| |
| Df(x) = \frac{4 A(1, 2) - A(1,1)}{4 - 1} + O(h^4) |
| |
| which is an approximation of :math:`Df(x)` with truncation error that |
| goes down as :math:`O(h^4)`. But we do not have to stop here. We can |
| iterate this process to obtain even more accurate estimates as |
| follows: |
| |
| .. math:: |
| |
| A(n, m) = \begin{cases} |
| \frac{\displaystyle f(x + h/2^{m-1}) - f(x - |
| h/2^{m-1})}{\displaystyle 2h/2^{m-1}} & n = 1 \\ |
| \frac{\displaystyle 4^{n-1} A(n - 1, m + 1) - A(n - 1, m)}{\displaystyle 4^{n-1} - 1} & n > 1 |
| \end{cases} |
| |
| It is straightforward to show that the approximation error in |
| :math:`A(n, 1)` is :math:`O(h^{2n})`. To see how the above formula can |
| be implemented in practice to compute :math:`A(n,1)` it is helpful to |
| structure the computation as the following tableau: |
| |
| .. math:: |
| \begin{array}{ccccc} |
| A(1,1) & A(1, 2) & A(1, 3) & A(1, 4) & \cdots\\ |
| & A(2, 1) & A(2, 2) & A(2, 3) & \cdots\\ |
| & & A(3, 1) & A(3, 2) & \cdots\\ |
| & & & A(4, 1) & \cdots \\ |
| & & & & \ddots |
| \end{array} |
| |
| So, to compute :math:`A(n, 1)` for increasing values of :math:`n` we |
| move from the left to the right, computing one column at a |
| time. Assuming that the primary cost here is the evaluation of the |
| function :math:`f(x)`, the cost of computing a new column of the above |
| tableau is two function evaluations. Since the cost of evaluating |
| :math:`A(1, n)`, requires evaluating the central difference formula |
| for step size of :math:`2^{1-n}h` |
| |
| Applying this method to :math:`f(x) = \frac{e^x}{\sin x - x^2}` |
| starting with a fairly large step size :math:`h = 0.01`, we get: |
| |
| .. math:: |
| \begin{array}{rrrrr} |
| 141.678097131 &140.971663667 &140.796145400 &140.752333523 &140.741384778\\ |
| &140.736185846 &140.737639311 &140.737729564 &140.737735196\\ |
| & &140.737736209 &140.737735581 &140.737735571\\ |
| & & &140.737735571 &140.737735571\\ |
| & & & &140.737735571\\ |
| \end{array} |
| |
| Compared to the *correct* value :math:`Df(1.0) = 140.73773557129658`, |
| :math:`A(5, 1)` has a relative error of :math:`10^{-13}`. For |
| comparison, the relative error for the central difference formula with |
| the same stepsize (:math:`0.01/2^4 = 0.000625`) is :math:`10^{-5}`. |
| |
| The above tableau is the basis of Ridders' method for numeric |
| differentiation. The full implementation is an adaptive scheme that |
| tracks its own estimation error and stops automatically when the |
| desired precision is reached. Of course it is more expensive than the |
| forward and central difference formulae, but is also significantly |
| more robust and accurate. |
| |
| Using Ridder's method instead of forward or central differences in |
| Ceres is again a simple matter of changing a template argument to |
| :class:`NumericDiffCostFunction` as follows: |
| |
| .. code-block:: c++ |
| |
| CostFunction* cost_function = |
| new NumericDiffCostFunction<Rat43CostFunctor, RIDDERS, 1, 4>( |
| new Rat43CostFunctor(x, y)); |
| |
| The following graph shows the relative error of the three methods as a |
| function of the absolute step size. For Ridders's method we assume |
| that the step size for evaluating :math:`A(n,1)` is :math:`2^{1-n}h`. |
| |
| .. figure:: forward_central_ridders_error.png |
| :figwidth: 100% |
| :align: center |
| |
| Using the 10 function evaluations that are needed to compute |
| :math:`A(5,1)` we are able to approximate :math:`Df(1.0)` about a 1000 |
| times better than the best central differences estimate. To put these |
| numbers in perspective, machine epsilon for double precision |
| arithmetic is :math:`\approx 2.22 \times 10^{-16}`. |
| |
| Going back to ``Rat43``, let us also look at the runtime cost of the |
| various methods for computing numeric derivatives. |
| |
| ========================== ========= |
| CostFunction Time (ns) |
| ========================== ========= |
| Rat43Analytic 255 |
| Rat43AnalyticOptimized 92 |
| Rat43NumericDiffForward 262 |
| Rat43NumericDiffCentral 517 |
| Rat43NumericDiffRidders 3760 |
| ========================== ========= |
| |
| As expected, Central Differences is about twice as expensive as |
| Forward Differences and the remarkable accuracy improvements of |
| Ridders' method cost an order of magnitude more runtime. |
| |
| Recommendations |
| =============== |
| |
| Numeric differentiation should be used when you cannot compute the |
| derivatives either analytically or using automatic differention. This |
| is usually the case when you are calling an external library or |
| function whose analytic form you do not know or even if you do, you |
| are not in a position to re-write it in a manner required to use |
| :ref:`chapter-automatic_derivatives`. |
| |
| |
| When using numeric differentiation, use at least Central Differences, |
| and if execution time is not a concern or the objective function is |
| such that determining a good static relative step size is hard, |
| Ridders' method is recommended. |
| |
| .. rubric:: Footnotes |
| |
| .. [#f2] `Numerical Differentiation |
| <https://en.wikipedia.org/wiki/Numerical_differentiation#Practical_considerations_using_floating_point_arithmetic>`_ |
| .. [#f3] [Press]_ Numerical Recipes, Section 5.7 |
| .. [#f4] In asymptotic error analysis, an error of :math:`O(h^k)` |
| means that the absolute-value of the error is at most some |
| constant times :math:`h^k` when :math:`h` is close enough to |
| :math:`0`. |