{-# LANGUAGE RebindableSyntax #-}
+{-# LANGUAGE ScopedTypeVariables #-}
-- | The Roots.Simple module contains root-finding algorithms. That
-- is, procedures to (numerically) find solutions to the equation,
-- where f is assumed to be continuous on the interval of interest.
--
-module Roots.Simple
+module Roots.Simple (
+ bisect,
+ fixed_point,
+ fixed_point_error_ratios,
+ fixed_point_iteration_count,
+ has_root,
+ newtons_method,
+ secant_method,
+ trisect )
where
import Data.List (find)
+import NumericPrelude hiding ( abs )
+import Algebra.Absolute ( abs )
+import qualified Algebra.Additive as Additive ( C )
+import qualified Algebra.Algebraic as Algebraic ( C )
+import qualified Algebra.Field as Field ( C )
+import qualified Algebra.RealField as RealField ( C )
+import qualified Algebra.RealRing as RealRing ( C )
-import Normed
+import Normed ( Normed(..) )
+import qualified Roots.Fast as F (
+ bisect,
+ fixed_point_iterations,
+ fixed_point_with_iterations,
+ has_root,
+ trisect )
-import qualified Roots.Fast as F
-
-import NumericPrelude hiding (abs)
-import qualified Algebra.Absolute as Absolute
-import Algebra.Absolute (abs)
-import qualified Algebra.Field as Field
-import qualified Algebra.RealField as RealField
-import qualified Algebra.RealRing as RealRing
-- | Does the (continuous) function @f@ have a root on the interval
-- [a,b]? If f(a) <] 0 and f(b) ]> 0, we know that there's a root in
-- | We are given a function @f@ and an interval [a,b]. The bisection
--- method checks finds a root by splitting [a,b] in half repeatedly.
+-- method finds a root by splitting [a,b] in half repeatedly.
--
-- If one is found within some prescribed tolerance @epsilon@, it is
-- returned. Otherwise, the interval [a,b] is split into two
--
-- Examples:
--
--- >>> bisect cos 1 2 0.001
--- Just 1.5712890625
+-- >>> let actual = 1.5707963267948966
+-- >>> let Just root = bisect cos 1 2 0.001
+-- >>> root
+-- 1.5712890625
+-- >>> abs (root - actual) < 0.001
+-- True
--
-- >>> bisect sin (-1) 1 0.001
-- Just 0.0
F.bisect f a b epsilon Nothing Nothing
+-- | We are given a function @f@ and an interval [a,b]. The trisection
+-- method finds a root by splitting [a,b] into three
+-- subintervals repeatedly.
+--
+-- If one is found within some prescribed tolerance @epsilon@, it is
+-- returned. Otherwise, the interval [a,b] is split into two
+-- subintervals [a,c] and [c,b] of equal length which are then both
+-- checked via the same process.
+--
+-- Returns 'Just' the value x for which f(x) == 0 if one is found,
+-- or Nothing if one of the preconditions is violated.
+--
+-- Examples:
+--
+-- >>> let actual = 1.5707963267948966
+-- >>> let Just root = trisect cos 1 2 0.001
+-- >>> root
+-- 1.5713305898491083
+-- >>> abs (root - actual) < 0.001
+-- True
+--
+-- >>> trisect sin (-1) 1 0.001
+-- Just 0.0
+--
+trisect :: (RealField.C a, RealRing.C b)
+ => (a -> b) -- ^ The function @f@ whose root we seek
+ -> a -- ^ The \"left\" endpoint of the interval, @a@
+ -> a -- ^ The \"right\" endpoint of the interval, @b@
+ -> a -- ^ The tolerance, @epsilon@
+ -> Maybe a
+trisect f a b epsilon =
+ F.trisect f a b epsilon Nothing Nothing
+
+
-- | Find a fixed point of the function @f@ with the search starting
-- at x0. We delegate to the version that returns the number of
-- iterations and simply discard the number of iterations.
--
-fixed_point :: (Normed a, RealField.C b)
+fixed_point :: (Normed a, Additive.C a, Algebraic.C b, RealField.C b)
=> (a -> a) -- ^ The function @f@ to iterate.
-> b -- ^ The tolerance, @epsilon@.
-> a -- ^ The initial value @x0@.
-- the function @f@ with the search starting at x0 and tolerance
-- @epsilon@. We delegate to the version that returns the number of
-- iterations and simply discard the fixed point.
-fixed_point_iteration_count :: (Normed a, RealField.C b)
+fixed_point_iteration_count :: (Normed a,
+ Additive.C a,
+ RealField.C b,
+ Algebraic.C b)
=> (a -> a) -- ^ The function @f@ to iterate.
-> b -- ^ The tolerance, @epsilon@.
-> a -- ^ The initial value @x0@.
--
-- This is used to determine the rate of convergence.
--
-fixed_point_error_ratios :: (Normed a, RealField.C b)
+fixed_point_error_ratios :: forall a b. (Normed a,
+ Additive.C a,
+ RealField.C b,
+ Algebraic.C b)
=> (a -> a) -- ^ The function @f@ to iterate.
-> a -- ^ The initial value @x0@.
-> a -- ^ The true solution, @x_star@.
zipWith (/) en_plus_one en_exp
where
xn = F.fixed_point_iterations f x0
- en = map (\x -> norm (x_star - x)) xn
+ en = map (\x -> norm (x_star - x)) xn :: [b]
en_plus_one = tail en
en_exp = map (^p) en
-- Examples:
--
-- Atkinson, p. 60.
+--
-- >>> let f x = x^6 - x - 1
-- >>> let f' x = 6*x^5 - 1
-- >>> tail $ take 4 $ newton_iterations f f' 2
-> (a -> a) -- ^ The derivative of @f@
-> a -- ^ Initial guess, x-naught
-> [a]
-newton_iterations f f' x0 =
- iterate next x0
+newton_iterations f f' =
+ iterate next
where
next xn =
xn - ( (f xn) / (f' xn) )
-- Examples:
--
-- Atkinson, p. 67.
+--
-- >>> let f x = x^6 - x - 1
-- >>> take 4 $ secant_iterations f 2 1
-- [2.0,1.0,1.0161290322580645,1.190577768676638]
-> a -- ^ Initial guess, x-naught
-> a -- ^ Second initial guess, x-one
-> [a]
-secant_iterations f x0 x1 =
- iterate2 g x0 x1
+secant_iterations f =
+ iterate2 g
where
g prev2 prev1 =
let x_change = prev1 - prev2
-- Examples:
--
-- Atkinson, p. 67.
+--
-- >>> let f x = x^6 - x - 1
-- >>> let Just root = secant_method f (1/10^9) 2 1
-- >>> root
projects / numerical-analysis.git / blobdiff