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Taddeüs Kroes
trs
Commits
5445504d
Commit
5445504d
authored
Apr 17, 2012
by
Taddeus Kroes
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Added shortcut rules for derivatives with 'ln(e)', (more) corrseponding to the VWO function list.
parent
00241cdd
Changes
3
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3 changed files
with
18 additions
and
13 deletions
+18
-13
src/rules/__init__.py
src/rules/__init__.py
+2
-3
src/rules/derivatives.py
src/rules/derivatives.py
+13
-8
src/rules/logarithmic.py
src/rules/logarithmic.py
+3
-2
No files found.
src/rules/__init__.py
View file @
5445504d
...
...
@@ -7,8 +7,7 @@ from .powers import match_add_exponents, match_subtract_exponents, \
match_raised_fraction
,
match_remove_negative_exponent
,
\
match_exponent_to_root
,
match_extend_exponent
,
match_constant_exponent
from
.numerics
import
match_add_numerics
,
match_divide_numerics
,
\
match_multiply_numerics
,
match_multiply_zero
,
match_multiply_one
,
\
match_raise_numerics
match_multiply_numerics
,
match_multiply_zero
,
match_raise_numerics
from
.fractions
import
match_constant_division
,
match_add_fractions
,
\
match_multiply_fractions
,
match_divide_fractions
,
\
match_extract_fraction_terms
...
...
@@ -36,7 +35,7 @@ RULES = {
match_combine_groups
,
match_add_quadrants
,
match_add_logarithms
],
OP_MUL
:
[
match_multiply_numerics
,
match_expand
,
match_add_exponents
,
match_multiply_zero
,
match_negated_factor
,
match_multiply_one
,
match_multiply_zero
,
match_negated_factor
,
match_sort_multiplicants
,
match_multiply_fractions
,
match_factor_in_multiplicant
],
OP_DIV
:
[
match_subtract_exponents
,
match_divide_numerics
,
...
...
src/rules/derivatives.py
View file @
5445504d
...
...
@@ -200,11 +200,14 @@ def variable_exponent(root, args):
"""
der(g ^ x, x) -> g ^ x * ln(g)
Note that (in combination with logarithmic/constant rules
):
der(e ^ x
) -> e ^ x * ln(e) -> e ^ x * 1
-> e ^ x
Shortcut rule (because of presence on formula list
):
der(e ^ x
, x)
-> e ^ x
"""
g
,
x
=
root
[
0
]
if
g
==
E
:
return
g
**
x
return
g
**
x
*
ln
(
g
)
...
...
@@ -236,10 +239,16 @@ def match_logarithmic(node):
def
logarithmic
(
root
,
args
):
"""
der(log(x, g), x) -> 1 / (x * ln(g))
der(log(x, g), x) -> 1 / (xln(g))
Shortcut function (because of presence on formula list):
der(ln(x), x) -> 1 / x
"""
x
,
g
=
root
[
0
]
if
g
==
E
:
return
L
(
1
)
/
x
return
L
(
1
)
/
(
x
*
ln
(
g
))
...
...
@@ -331,13 +340,9 @@ def match_sum_product_rule(node):
if
len
(
functions
)
<
2
:
return
[]
p
=
[]
handler
=
sum_rule
if
node
[
0
].
op
==
OP_ADD
else
product_rule
for
f
in
functions
:
p
.
append
(
P
(
node
,
handler
,
(
scope
,
f
)))
return
p
return
[
P
(
node
,
handler
,
(
scope
,
f
))
for
f
in
functions
]
def
sum_rule
(
root
,
args
):
...
...
src/rules/logarithmic.py
View file @
5445504d
...
...
@@ -179,7 +179,8 @@ def match_raised_base(node):
logs
,
others
=
partition
(
is_matching_logarithm
,
scope
)
for
other
,
log
in
product
(
others
,
logs
):
# TODO: Give this function a high precedence
# Add this possibility so that a 'raised_base' possibility is
# generated in the following iteration
p
.
append
(
P
(
node
,
factor_in_exponent_multiplicant
,
(
scope
,
other
,
log
)))
...
...
@@ -250,7 +251,7 @@ MESSAGES[factor_out_exponent] = _('Factor out exponent {0[0][0]} from {0}.')
def
match_factor_in_multiplicant
(
node
):
"""
Only bring a multiplicant inside a logarithm
s
if both the multiplicant and
Only bring a multiplicant inside a logarithm if both the multiplicant and
the logaritm's content are constants. This will yield a new simplification
of constants inside the logarithm.
2log(2) -> log(2 ^ 2) # -> log(4)
...
...
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