These are functions so that you can write foo(x) instead of x.foo() in certain common cases.
AUTHORS:
Returns a numerical approximation of an object x with at least prec bits (or decimal digits) of precision.
Note
Both upper case N and lower case n are aliases for numerical_approx(), and all three may be used as methods.
INPUT:
If neither the prec or digits are specified, the default is 53 bits of precision. If both are specified, then prec is used.
EXAMPLES:
sage: numerical_approx(pi, 10)
3.1
sage: numerical_approx(pi, digits=10)
3.141592654
sage: numerical_approx(pi^2 + e, digits=20)
12.587886229548403854
sage: n(pi^2 + e)
12.5878862295484
sage: N(pi^2 + e)
12.5878862295484
sage: n(pi^2 + e, digits=50)
12.587886229548403854194778471228813633070946500941
sage: a = CC(-5).n(prec=100)
sage: b = ComplexField(100)(-5)
sage: a == b
True
sage: type(a) == type(b)
True
sage: numerical_approx(9)
9.00000000000000
You can also usually use method notation.
sage: (pi^2 + e).n()
12.5878862295484
sage: (pi^2 + e).N()
12.5878862295484
sage: (pi^2 + e).numerical_approx()
12.5878862295484
Vectors and matrices may also have their entries approximated.
sage: v = vector(RDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: v = vector(CDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: _.parent()
Vector space of dimension 3 over Complex Field with 53 bits of precision
sage: v.n(prec=75)
(1.000000000000000000000, 2.000000000000000000000, 3.000000000000000000000)
sage: u = vector(QQ, [1/2, 1/3, 1/4])
sage: n(u, prec=15)
(0.5000, 0.3333, 0.2500)
sage: n(u, digits=5)
(0.50000, 0.33333, 0.25000)
sage: v = vector(QQ, [1/2, 0, 0, 1/3, 0, 0, 0, 1/4], sparse=True)
sage: u = v.numerical_approx(digits=4)
sage: u.is_sparse()
True
sage: u
(0.5000, 0.0000, 0.0000, 0.3333, 0.0000, 0.0000, 0.0000, 0.2500)
sage: A = matrix(QQ, 2, 3, range(6))
sage: A.n()
[0.000000000000000 1.00000000000000 2.00000000000000]
[ 3.00000000000000 4.00000000000000 5.00000000000000]
sage: B = matrix(Integers(12), 3, 8, srange(24))
sage: N(B, digits=2)
[0.00 1.0 2.0 3.0 4.0 5.0 6.0 7.0]
[ 8.0 9.0 10. 11. 0.00 1.0 2.0 3.0]
[ 4.0 5.0 6.0 7.0 8.0 9.0 10. 11.]
Internally, numerical approximations of real numbers are stored in base-2. Therefore, numbers which look the same in their decimal expansion might be different:
sage: x=N(pi, digits=3); x
3.14
sage: y=N(3.14, digits=3); y
3.14
sage: x==y
False
sage: x.str(base=2)
'11.001001000100'
sage: y.str(base=2)
'11.001000111101'
As an exceptional case, digits=1 usually leads to 2 digits (one significant) in the decimal output (see trac ticket #11647):
sage: N(pi, digits=1)
3.2
sage: N(pi, digits=2)
3.1
sage: N(100*pi, digits=1)
320.
sage: N(100*pi, digits=2)
310.
In the following example, pi and 3 are both approximated to two bits of precision and then subtracted, which kills two bits of precision:
sage: N(pi, prec=2)
3.0
sage: N(3, prec=2)
3.0
sage: N(pi - 3, prec=2)
0.00
TESTS:
sage: numerical_approx(I)
1.00000000000000*I
sage: x = QQ['x'].gen()
sage: F.<k> = NumberField(x^2+2, embedding=sqrt(CC(2))*CC.0)
sage: numerical_approx(k)
1.41421356237309*I
sage: type(numerical_approx(CC(1/2)))
<type 'sage.rings.complex_number.ComplexNumber'>
The following tests trac ticket #10761, in which n() would break when called on complex-valued algebraic numbers.
sage: E = matrix(3, [3,1,6,5,2,9,7,3,13]).eigenvalues(); E
[18.16815365088822?, -0.08407682544410650? - 0.2190261484802906?*I, -0.08407682544410650? + 0.2190261484802906?*I]
sage: E[1].parent()
Algebraic Field
sage: [a.n() for a in E]
[18.1681536508882, -0.0840768254441065 - 0.219026148480291*I, -0.0840768254441065 + 0.219026148480291*I]
Make sure we’ve rounded up log(10,2) enough to guarantee sufficient precision (trac #10164):
sage: ks = 4*10**5, 10**6
sage: check_str_length = lambda k: len(str(numerical_approx(1+10**-k,digits=k+1)))-1 >= k+1
sage: check_precision = lambda k: numerical_approx(1+10**-k,digits=k+1)-1 > 0
sage: all(check_str_length(k) and check_precision(k) for k in ks)
True
Testing we have sufficient precision for the golden ratio (trac #12163), note that the decimal point adds 1 to the string length:
sage: len(str(n(golden_ratio, digits=5000))) 5001 sage: len(str(n(golden_ratio, digits=5000000))) # long time (4s on sage.math, 2012) 5000001
Returns the arc cosine of x.
EXAMPLES:
sage: acos(.5)
1.04719755119660
sage: acos(sin(pi/3))
arccos(1/2*sqrt(3))
sage: acos(sin(pi/3)).simplify_full()
1/6*pi
Returns the additive order of .
EXAMPLES:
sage: additive_order(5)
+Infinity
sage: additive_order(Mod(5,11))
11
sage: additive_order(Mod(4,12))
3
Returns the arc sine of x.
EXAMPLES:
sage: asin(.5)
0.523598775598299
sage: asin(sin(pi/3))
arcsin(1/2*sqrt(3))
sage: asin(sin(pi/3)).simplify_full()
1/3*pi
Returns the arc tangent of x.
EXAMPLES:
sage: z = atan(3);z
arctan(3)
sage: n(z)
1.24904577239825
sage: atan(tan(pi/4))
1/4*pi
Returns the base field over which x is defined.
EXAMPLES:
sage: R = PolynomialRing(GF(7), 'x')
sage: base_ring(R)
Finite Field of size 7
sage: base_field(R)
Finite Field of size 7
This catches base rings which are fields as well, but does not implement a base_field method for objects which do not have one:
sage: R.base_field()
Traceback (most recent call last):
...
AttributeError: 'PolynomialRing_dense_mod_p_with_category' object has no attribute 'base_field'
Returns the base ring over which x is defined.
EXAMPLES:
sage: R = PolynomialRing(GF(7), 'x')
sage: base_ring(R)
Finite Field of size 7
Returns the fixed basis of x.
EXAMPLES:
sage: V = VectorSpace(QQ,3)
sage: S = V.subspace([[1,2,0],[2,2,-1]])
sage: basis(S)
[
(1, 0, -1),
(0, 1, 1/2)
]
Returns the category of x.
EXAMPLES:
sage: V = VectorSpace(QQ,3)
sage: category(V)
Category of vector spaces over Rational Field
Returns the ceiling (least integer) function of x.
EXAMPLES:
sage: ceil(3.5)
4
sage: ceil(7/2)
4
sage: ceil(-3.5)
-3
sage: ceil(RIF(1.3,2.3))
3.?
Returns the characteristic polynomial of x in the given variable.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: charpoly(A)
x^3 - 15*x^2 - 18*x
sage: charpoly(A, 't')
t^3 - 15*t^2 - 18*t
sage: k.<alpha> = GF(7^10); k
Finite Field in alpha of size 7^10
sage: alpha.charpoly('T')
T^10 + T^6 + T^5 + 4*T^4 + T^3 + 2*T^2 + 3*T + 3
sage: characteristic_polynomial(alpha, 'T')
T^10 + T^6 + T^5 + 4*T^4 + T^3 + 2*T^2 + 3*T + 3
Returns the characteristic polynomial of x in the given variable.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: charpoly(A)
x^3 - 15*x^2 - 18*x
sage: charpoly(A, 't')
t^3 - 15*t^2 - 18*t
sage: k.<alpha> = GF(7^10); k
Finite Field in alpha of size 7^10
sage: alpha.charpoly('T')
T^10 + T^6 + T^5 + 4*T^4 + T^3 + 2*T^2 + 3*T + 3
sage: characteristic_polynomial(alpha, 'T')
T^10 + T^6 + T^5 + 4*T^4 + T^3 + 2*T^2 + 3*T + 3
Attempts to coerce x to type P if possible.
EXAMPLES:
sage: type(5)
<type 'sage.rings.integer.Integer'>
sage: type(coerce(QQ,5))
<type 'sage.rings.rational.Rational'>
Returns the cyclotomic polynomial.
EXAMPLES:
sage: cyclotomic_polynomial(3)
x^2 + x + 1
sage: cyclotomic_polynomial(4)
x^2 + 1
sage: cyclotomic_polynomial(9)
x^6 + x^3 + 1
sage: cyclotomic_polynomial(10)
x^4 - x^3 + x^2 - x + 1
sage: cyclotomic_polynomial(11)
x^10 + x^9 + x^8 + x^7 + x^6 + x^5 + x^4 + x^3 + x^2 + x + 1
Returns the decomposition of x.
EXAMPLES:
sage: M = matrix([[2, 3], [3, 4]])
sage: M.decomposition()
[
(Ambient free module of rank 2 over the principal ideal domain Integer Ring, True)
]
sage: G.<a,b> = DirichletGroup(20)
sage: c = a*b
sage: d = c.decomposition(); d
[Dirichlet character modulo 4 of conductor 4 mapping 3 |--> -1,
Dirichlet character modulo 5 of conductor 5 mapping 2 |--> zeta4]
sage: d[0].parent()
Group of Dirichlet characters of modulus 4 over Cyclotomic Field of order 4 and degree 2
Returns the denominator of x.
EXAMPLES:
sage: denominator(17/11111)
11111
sage: R.<x> = PolynomialRing(QQ)
sage: F = FractionField(R)
sage: r = (x+1)/(x-1)
sage: denominator(r)
x - 1
Returns the determinant of x.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: det(A)
0
Returns the dimension of x.
EXAMPLES:
sage: V = VectorSpace(QQ,3)
sage: S = V.subspace([[1,2,0],[2,2,-1]])
sage: dimension(S)
2
Returns the dimension of x.
EXAMPLES:
sage: V = VectorSpace(QQ,3)
sage: S = V.subspace([[1,2,0],[2,2,-1]])
sage: dimension(S)
2
Returns the discriminant of x.
EXAMPLES:
sage: R.<x> = PolynomialRing(QQ)
sage: S = R.quotient(x^29 - 17*x - 1, 'alpha')
sage: K = S.number_field()
sage: discriminant(K)
-15975100446626038280218213241591829458737190477345113376757479850566957249523
Returns the discriminant of x.
EXAMPLES:
sage: R.<x> = PolynomialRing(QQ)
sage: S = R.quotient(x^29 - 17*x - 1, 'alpha')
sage: K = S.number_field()
sage: discriminant(K)
-15975100446626038280218213241591829458737190477345113376757479850566957249523
Returns the value of the eta function at , which must be
in the upper half plane.
The function is
EXAMPLES:
sage: eta(1+I)
0.742048775837 + 0.19883137023*I
Returns the value of the exponentiation function at x.
EXAMPLES:
sage: exp(3)
e^3
sage: exp(0)
1
sage: exp(2.5)
12.1824939607035
sage: exp(pi*i)
-1
Returns the (prime) factorization of x.
EXAMPLES:
sage: factor(factorial(10))
2^8 * 3^4 * 5^2 * 7
sage: n = next_prime(10^6); n
1000003
sage: factor(n)
1000003
Note that this depends on the type of x::
sage: factor(55)
5 * 11
sage: factor(x^2+2*x+1)
(x + 1)^2
sage: factor(55*x^2+110*x+55)
55*(x + 1)^2
Returns the (prime) factorization of x.
EXAMPLES:
sage: factor(factorial(10))
2^8 * 3^4 * 5^2 * 7
sage: n = next_prime(10^6); n
1000003
sage: factor(n)
1000003
Note that this depends on the type of x::
sage: factor(55)
5 * 11
sage: factor(x^2+2*x+1)
(x + 1)^2
sage: factor(55*x^2+110*x+55)
55*(x + 1)^2
Returns the (prime) factorization of x.
EXAMPLES:
sage: factor(factorial(10))
2^8 * 3^4 * 5^2 * 7
sage: n = next_prime(10^6); n
1000003
sage: factor(n)
1000003
Note that this depends on the type of x::
sage: factor(55)
5 * 11
sage: factor(x^2+2*x+1)
(x + 1)^2
sage: factor(55*x^2+110*x+55)
55*(x + 1)^2
Returns the factorization of the characteristic polynomial of x.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: fcp(A, 'x')
x * (x^2 - 15*x - 18)
Returns the generator of x.
EXAMPLES:
sage: R.<x> = QQ[]; R
Univariate Polynomial Ring in x over Rational Field
sage: gen(R)
x
sage: gen(GF(7))
1
sage: A = AbelianGroup(1, [23])
sage: gen(A)
f
Returns the generators of x.
EXAMPLES:
sage: R.<x,y> = SR[]
sage: R
Multivariate Polynomial Ring in x, y over Symbolic Ring
sage: gens(R)
(x, y)
sage: A = AbelianGroup(5, [5,5,7,8,9])
sage: gens(A)
(f0, f1, f2, f3, f4)
Returns the n-th Hecke operator T_n acting on x.
EXAMPLES:
sage: M = ModularSymbols(1,12)
sage: hecke_operator(M,5)
Hecke operator T_5 on Modular Symbols space of dimension 3 for Gamma_0(1) of weight 12 with sign 0 over Rational Field
Returns the image of x.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: image(A)
Vector space of degree 3 and dimension 2 over Rational Field
Basis matrix:
[ 1 0 -1]
[ 0 1 2]
Returns an indefinite or definite integral of an object x.
First call x.integral() and if that fails make an object and integrate it using Maxima, maple, etc, as specified by algorithm.
For symbolic expression calls sage.calculus.calculus.integral() - see this function for available options.
EXAMPLES:
sage: f = cyclotomic_polynomial(10)
sage: integral(f)
1/5*x^5 - 1/4*x^4 + 1/3*x^3 - 1/2*x^2 + x
sage: integral(sin(x),x)
-cos(x)
sage: y = var('y')
sage: integral(sin(x),y)
y*sin(x)
sage: integral(sin(x), x, 0, pi/2)
1
sage: sin(x).integral(x, 0,pi/2)
1
sage: integral(exp(-x), (x, 1, oo))
e^(-1)
Numerical approximation:
sage: h = integral(tan(x)/x, (x, 1, pi/3)); h
integrate(tan(x)/x, x, 1, 1/3*pi)
sage: h.n()
0.07571599101...
Specific algorithm can be used for integration:
sage: integral(sin(x)^2, x, algorithm='maxima')
1/2*x - 1/4*sin(2*x)
sage: integral(sin(x)^2, x, algorithm='sympy')
-1/2*cos(x)*sin(x) + 1/2*x
TESTS:
A symbolic integral from trac ticket #11445 that was incorrect in earlier versions of Maxima:
sage: f = abs(x - 1) + abs(x + 1) - 2*abs(x)
sage: integrate(f, (x, -Infinity, Infinity))
2
Another symbolic integral, from trac ticket #11238, that used to return zero incorrectly; with maxima 5.26.0 one gets 1/2*sqrt(pi)*e^(1/4), whereas with 5.29.1 the expression is less pleasant, but still has the same value:
sage: f = exp(-x) * sinh(sqrt(x))
sage: t = integrate(f, x, 0, Infinity); t # long time
1/4*(sqrt(pi)*(erf(1) - 1) + sqrt(pi) + 2*e^(-1) - 2)*e^(1/4) - 1/4*(sqrt(pi)*(erf(1) - 1) - sqrt(pi) + 2*e^(-1) - 2)*e^(1/4)
sage: t.simplify_exp() # long time
1/2*sqrt(pi)*e^(1/4)
An integral which used to return -1 before maxima 5.28. See trac ticket #12842:
sage: f = e^(-2*x)/sqrt(1-e^(-2*x))
sage: integrate(f, x, 0, infinity)
1
This integral would cause a stack overflow in earlier versions of Maxima, crashing sage. See trac ticket #12377. We don’t care about the result here, just that the computation completes successfully:
sage: y = (x^2)*exp(x) / (1 + exp(x))^2
sage: _ = integrate(y, x, -1000, 1000)
Returns the integral closure of x.
EXAMPLES:
sage: integral_closure(QQ)
Rational Field
sage: K.<a> = QuadraticField(5)
sage: O2 = K.order(2*a); O2
Order in Number Field in a with defining polynomial x^2 - 5
sage: integral_closure(O2)
Maximal Order in Number Field in a with defining polynomial x^2 - 5
Returns an indefinite or definite integral of an object x.
First call x.integral() and if that fails make an object and integrate it using Maxima, maple, etc, as specified by algorithm.
For symbolic expression calls sage.calculus.calculus.integral() - see this function for available options.
EXAMPLES:
sage: f = cyclotomic_polynomial(10)
sage: integral(f)
1/5*x^5 - 1/4*x^4 + 1/3*x^3 - 1/2*x^2 + x
sage: integral(sin(x),x)
-cos(x)
sage: y = var('y')
sage: integral(sin(x),y)
y*sin(x)
sage: integral(sin(x), x, 0, pi/2)
1
sage: sin(x).integral(x, 0,pi/2)
1
sage: integral(exp(-x), (x, 1, oo))
e^(-1)
Numerical approximation:
sage: h = integral(tan(x)/x, (x, 1, pi/3)); h
integrate(tan(x)/x, x, 1, 1/3*pi)
sage: h.n()
0.07571599101...
Specific algorithm can be used for integration:
sage: integral(sin(x)^2, x, algorithm='maxima')
1/2*x - 1/4*sin(2*x)
sage: integral(sin(x)^2, x, algorithm='sympy')
-1/2*cos(x)*sin(x) + 1/2*x
TESTS:
A symbolic integral from trac ticket #11445 that was incorrect in earlier versions of Maxima:
sage: f = abs(x - 1) + abs(x + 1) - 2*abs(x)
sage: integrate(f, (x, -Infinity, Infinity))
2
Another symbolic integral, from trac ticket #11238, that used to return zero incorrectly; with maxima 5.26.0 one gets 1/2*sqrt(pi)*e^(1/4), whereas with 5.29.1 the expression is less pleasant, but still has the same value:
sage: f = exp(-x) * sinh(sqrt(x))
sage: t = integrate(f, x, 0, Infinity); t # long time
1/4*(sqrt(pi)*(erf(1) - 1) + sqrt(pi) + 2*e^(-1) - 2)*e^(1/4) - 1/4*(sqrt(pi)*(erf(1) - 1) - sqrt(pi) + 2*e^(-1) - 2)*e^(1/4)
sage: t.simplify_exp() # long time
1/2*sqrt(pi)*e^(1/4)
An integral which used to return -1 before maxima 5.28. See trac ticket #12842:
sage: f = e^(-2*x)/sqrt(1-e^(-2*x))
sage: integrate(f, x, 0, infinity)
1
This integral would cause a stack overflow in earlier versions of Maxima, crashing sage. See trac ticket #12377. We don’t care about the result here, just that the computation completes successfully:
sage: y = (x^2)*exp(x) / (1 + exp(x))^2
sage: _ = integrate(y, x, -1000, 1000)
Integers between a and b inclusive (a and b integers).
EXAMPLES:
sage: I = interval(1,3)
sage: 2 in I
True
sage: 1 in I
True
sage: 4 in I
False
Returns whether or not x is commutative.
EXAMPLES:
sage: R = PolynomialRing(QQ, 'x')
sage: is_commutative(R)
True
Returns whether or not an integer x is even, e.g., divisible by 2.
EXAMPLES:
sage: is_even(-1)
False
sage: is_even(4)
True
sage: is_even(-2)
True
Returns whether or not x is a field.
EXAMPLES:
sage: R = PolynomialRing(QQ, 'x')
sage: F = FractionField(R)
sage: is_field(F)
True
Returns whether x is integrally closed.
EXAMPLES:
sage: is_integrally_closed(QQ)
True
sage: K.<a> = NumberField(x^2 + 189*x + 394)
sage: R = K.order(2*a)
sage: is_integrally_closed(R)
False
Returns whether or not x is a Noetherian object (has ascending chain condition).
EXAMPLES:
sage: from sage.misc.functional import is_noetherian
sage: is_noetherian(ZZ)
True
sage: is_noetherian(QQ)
True
sage: A = SteenrodAlgebra(3)
sage: is_noetherian(A)
False
Returns whether or not x is odd. This is by definition the complement of is_even.
EXAMPLES:
sage: is_odd(-2)
False
sage: is_odd(-3)
True
sage: is_odd(0)
False
sage: is_odd(1)
True
Returns an integer square root, i.e., the floor of a square root.
EXAMPLES:
sage: isqrt(10)
3
sage: isqrt(10r)
3
Returns the left kernel of x.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,2)
sage: A = M([1,2,3,4,5,6])
sage: kernel(A)
Vector space of degree 3 and dimension 1 over Rational Field
Basis matrix:
[ 1 -2 1]
sage: kernel(A.transpose())
Vector space of degree 2 and dimension 0 over Rational Field
Basis matrix:
[]
Returns the Krull dimension of x.
EXAMPLES:
sage: krull_dimension(QQ)
0
sage: krull_dimension(ZZ)
1
sage: krull_dimension(ZZ[sqrt(5)])
1
sage: U.<x,y,z> = PolynomialRing(ZZ,3); U
Multivariate Polynomial Ring in x, y, z over Integer Ring
sage: U.krull_dimension()
4
Lift an object of a quotient ring to
.
EXAMPLES: We lift an integer modulo .
sage: Mod(2,3).lift()
2
We lift an element of a quotient polynomial ring.
sage: R.<x> = QQ['x']
sage: S.<xmod> = R.quo(x^2 + 1)
sage: lift(xmod-7)
x - 7
Returns the log of x to the base b. The default base is e.
INPUT:
OUTPUT: number
Note
In Magma, the order of arguments is reversed from in Sage, i.e., the base is given first. We use the opposite ordering, so the base can be viewed as an optional second argument.
EXAMPLES:
sage: log(e^2)
2
sage: log(16,2)
4
sage: log(3.)
1.09861228866811
Returns the minimal polynomial of x.
EXAMPLES:
sage: a = matrix(ZZ, 2, [1..4])
sage: minpoly(a)
x^2 - 5*x - 2
sage: minpoly(a,'t')
t^2 - 5*t - 2
sage: minimal_polynomial(a)
x^2 - 5*x - 2
sage: minimal_polynomial(a,'theta')
theta^2 - 5*theta - 2
Returns the minimal polynomial of x.
EXAMPLES:
sage: a = matrix(ZZ, 2, [1..4])
sage: minpoly(a)
x^2 - 5*x - 2
sage: minpoly(a,'t')
t^2 - 5*t - 2
sage: minimal_polynomial(a)
x^2 - 5*x - 2
sage: minimal_polynomial(a,'theta')
theta^2 - 5*theta - 2
Returns the multiplicative order of self, if self is a unit, or raise ArithmeticError otherwise.
EXAMPLES:
sage: a = mod(5,11)
sage: multiplicative_order(a)
5
sage: multiplicative_order(mod(2,11))
10
sage: multiplicative_order(mod(2,12))
Traceback (most recent call last):
...
ArithmeticError: multiplicative order of 2 not defined since it is not a unit modulo 12
Returns a numerical approximation of an object x with at least prec bits (or decimal digits) of precision.
Note
Both upper case N and lower case n are aliases for numerical_approx(), and all three may be used as methods.
INPUT:
If neither the prec or digits are specified, the default is 53 bits of precision. If both are specified, then prec is used.
EXAMPLES:
sage: numerical_approx(pi, 10)
3.1
sage: numerical_approx(pi, digits=10)
3.141592654
sage: numerical_approx(pi^2 + e, digits=20)
12.587886229548403854
sage: n(pi^2 + e)
12.5878862295484
sage: N(pi^2 + e)
12.5878862295484
sage: n(pi^2 + e, digits=50)
12.587886229548403854194778471228813633070946500941
sage: a = CC(-5).n(prec=100)
sage: b = ComplexField(100)(-5)
sage: a == b
True
sage: type(a) == type(b)
True
sage: numerical_approx(9)
9.00000000000000
You can also usually use method notation.
sage: (pi^2 + e).n()
12.5878862295484
sage: (pi^2 + e).N()
12.5878862295484
sage: (pi^2 + e).numerical_approx()
12.5878862295484
Vectors and matrices may also have their entries approximated.
sage: v = vector(RDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: v = vector(CDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: _.parent()
Vector space of dimension 3 over Complex Field with 53 bits of precision
sage: v.n(prec=75)
(1.000000000000000000000, 2.000000000000000000000, 3.000000000000000000000)
sage: u = vector(QQ, [1/2, 1/3, 1/4])
sage: n(u, prec=15)
(0.5000, 0.3333, 0.2500)
sage: n(u, digits=5)
(0.50000, 0.33333, 0.25000)
sage: v = vector(QQ, [1/2, 0, 0, 1/3, 0, 0, 0, 1/4], sparse=True)
sage: u = v.numerical_approx(digits=4)
sage: u.is_sparse()
True
sage: u
(0.5000, 0.0000, 0.0000, 0.3333, 0.0000, 0.0000, 0.0000, 0.2500)
sage: A = matrix(QQ, 2, 3, range(6))
sage: A.n()
[0.000000000000000 1.00000000000000 2.00000000000000]
[ 3.00000000000000 4.00000000000000 5.00000000000000]
sage: B = matrix(Integers(12), 3, 8, srange(24))
sage: N(B, digits=2)
[0.00 1.0 2.0 3.0 4.0 5.0 6.0 7.0]
[ 8.0 9.0 10. 11. 0.00 1.0 2.0 3.0]
[ 4.0 5.0 6.0 7.0 8.0 9.0 10. 11.]
Internally, numerical approximations of real numbers are stored in base-2. Therefore, numbers which look the same in their decimal expansion might be different:
sage: x=N(pi, digits=3); x
3.14
sage: y=N(3.14, digits=3); y
3.14
sage: x==y
False
sage: x.str(base=2)
'11.001001000100'
sage: y.str(base=2)
'11.001000111101'
As an exceptional case, digits=1 usually leads to 2 digits (one significant) in the decimal output (see trac ticket #11647):
sage: N(pi, digits=1)
3.2
sage: N(pi, digits=2)
3.1
sage: N(100*pi, digits=1)
320.
sage: N(100*pi, digits=2)
310.
In the following example, pi and 3 are both approximated to two bits of precision and then subtracted, which kills two bits of precision:
sage: N(pi, prec=2)
3.0
sage: N(3, prec=2)
3.0
sage: N(pi - 3, prec=2)
0.00
TESTS:
sage: numerical_approx(I)
1.00000000000000*I
sage: x = QQ['x'].gen()
sage: F.<k> = NumberField(x^2+2, embedding=sqrt(CC(2))*CC.0)
sage: numerical_approx(k)
1.41421356237309*I
sage: type(numerical_approx(CC(1/2)))
<type 'sage.rings.complex_number.ComplexNumber'>
The following tests trac ticket #10761, in which n() would break when called on complex-valued algebraic numbers.
sage: E = matrix(3, [3,1,6,5,2,9,7,3,13]).eigenvalues(); E
[18.16815365088822?, -0.08407682544410650? - 0.2190261484802906?*I, -0.08407682544410650? + 0.2190261484802906?*I]
sage: E[1].parent()
Algebraic Field
sage: [a.n() for a in E]
[18.1681536508882, -0.0840768254441065 - 0.219026148480291*I, -0.0840768254441065 + 0.219026148480291*I]
Make sure we’ve rounded up log(10,2) enough to guarantee sufficient precision (trac #10164):
sage: ks = 4*10**5, 10**6
sage: check_str_length = lambda k: len(str(numerical_approx(1+10**-k,digits=k+1)))-1 >= k+1
sage: check_precision = lambda k: numerical_approx(1+10**-k,digits=k+1)-1 > 0
sage: all(check_str_length(k) and check_precision(k) for k in ks)
True
Testing we have sufficient precision for the golden ratio (trac #12163), note that the decimal point adds 1 to the string length:
sage: len(str(n(golden_ratio, digits=5000))) 5001 sage: len(str(n(golden_ratio, digits=5000000))) # long time (4s on sage.math, 2012) 5000001
Returns the number of generators of x.
EXAMPLES:
sage: R.<x,y> = SR[]; R
Multivariate Polynomial Ring in x, y over Symbolic Ring
sage: ngens(R)
2
sage: A = AbelianGroup(5, [5,5,7,8,9])
sage: ngens(A)
5
sage: ngens(ZZ)
1
Returns the norm of x.
For matrices and vectors, this returns the L2-norm. The L2-norm of a
vector , also called the Euclidean
norm, is defined as
where is the complex modulus of
. The Euclidean norm is often
used for determining the distance between two points in two- or
three-dimensional space.
For complex numbers, the function returns the field norm. If
is a complex number, then the norm of
is defined as the
product of
and its complex conjugate
The norm of a complex number is different from its absolute value.
The absolute value of a complex number is defined to be the square
root of its norm. A typical use of the complex norm is in the
integral domain of Gaussian integers, where the norm of
each Gaussian integer
is defined as its complex norm.
See also
EXAMPLES:
The norm of vectors:
sage: z = 1 + 2*I
sage: norm(vector([z]))
sqrt(5)
sage: v = vector([-1,2,3])
sage: norm(v)
sqrt(14)
sage: _ = var("a b c d")
sage: v = vector([a, b, c, d])
sage: norm(v)
sqrt(abs(a)^2 + abs(b)^2 + abs(c)^2 + abs(d)^2)
The norm of matrices:
sage: z = 1 + 2*I
sage: norm(matrix([[z]]))
2.2360679775
sage: M = matrix(ZZ, [[1,2,4,3], [-1,0,3,-10]])
sage: norm(M)
10.6903311292
sage: norm(CDF(z))
5.0
sage: norm(CC(z))
5.00000000000000
The norm of complex numbers:
sage: z = 2 - 3*I
sage: norm(z)
13
sage: a = randint(-10^10, 100^10)
sage: b = randint(-10^10, 100^10)
sage: z = a + b*I
sage: bool(norm(z) == a^2 + b^2)
True
The complex norm of symbolic expressions:
sage: a, b, c = var("a, b, c")
sage: assume((a, 'real'), (b, 'real'), (c, 'real'))
sage: z = a + b*I
sage: bool(norm(z).simplify() == a^2 + b^2)
True
sage: norm(a + b).simplify()
a^2 + 2*a*b + b^2
sage: v = vector([a, b, c])
sage: bool(norm(v).simplify() == sqrt(a^2 + b^2 + c^2))
True
sage: forget()
Returns the numerator of x.
EXAMPLES:
sage: R.<x> = PolynomialRing(QQ)
sage: F = FractionField(R)
sage: r = (x+1)/(x-1)
sage: numerator(r)
x + 1
sage: numerator(17/11111)
17
Returns a numerical approximation of an object x with at least prec bits (or decimal digits) of precision.
Note
Both upper case N and lower case n are aliases for numerical_approx(), and all three may be used as methods.
INPUT:
If neither the prec or digits are specified, the default is 53 bits of precision. If both are specified, then prec is used.
EXAMPLES:
sage: numerical_approx(pi, 10)
3.1
sage: numerical_approx(pi, digits=10)
3.141592654
sage: numerical_approx(pi^2 + e, digits=20)
12.587886229548403854
sage: n(pi^2 + e)
12.5878862295484
sage: N(pi^2 + e)
12.5878862295484
sage: n(pi^2 + e, digits=50)
12.587886229548403854194778471228813633070946500941
sage: a = CC(-5).n(prec=100)
sage: b = ComplexField(100)(-5)
sage: a == b
True
sage: type(a) == type(b)
True
sage: numerical_approx(9)
9.00000000000000
You can also usually use method notation.
sage: (pi^2 + e).n()
12.5878862295484
sage: (pi^2 + e).N()
12.5878862295484
sage: (pi^2 + e).numerical_approx()
12.5878862295484
Vectors and matrices may also have their entries approximated.
sage: v = vector(RDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: v = vector(CDF, [1,2,3])
sage: v.n()
(1.00000000000000, 2.00000000000000, 3.00000000000000)
sage: _.parent()
Vector space of dimension 3 over Complex Field with 53 bits of precision
sage: v.n(prec=75)
(1.000000000000000000000, 2.000000000000000000000, 3.000000000000000000000)
sage: u = vector(QQ, [1/2, 1/3, 1/4])
sage: n(u, prec=15)
(0.5000, 0.3333, 0.2500)
sage: n(u, digits=5)
(0.50000, 0.33333, 0.25000)
sage: v = vector(QQ, [1/2, 0, 0, 1/3, 0, 0, 0, 1/4], sparse=True)
sage: u = v.numerical_approx(digits=4)
sage: u.is_sparse()
True
sage: u
(0.5000, 0.0000, 0.0000, 0.3333, 0.0000, 0.0000, 0.0000, 0.2500)
sage: A = matrix(QQ, 2, 3, range(6))
sage: A.n()
[0.000000000000000 1.00000000000000 2.00000000000000]
[ 3.00000000000000 4.00000000000000 5.00000000000000]
sage: B = matrix(Integers(12), 3, 8, srange(24))
sage: N(B, digits=2)
[0.00 1.0 2.0 3.0 4.0 5.0 6.0 7.0]
[ 8.0 9.0 10. 11. 0.00 1.0 2.0 3.0]
[ 4.0 5.0 6.0 7.0 8.0 9.0 10. 11.]
Internally, numerical approximations of real numbers are stored in base-2. Therefore, numbers which look the same in their decimal expansion might be different:
sage: x=N(pi, digits=3); x
3.14
sage: y=N(3.14, digits=3); y
3.14
sage: x==y
False
sage: x.str(base=2)
'11.001001000100'
sage: y.str(base=2)
'11.001000111101'
As an exceptional case, digits=1 usually leads to 2 digits (one significant) in the decimal output (see trac ticket #11647):
sage: N(pi, digits=1)
3.2
sage: N(pi, digits=2)
3.1
sage: N(100*pi, digits=1)
320.
sage: N(100*pi, digits=2)
310.
In the following example, pi and 3 are both approximated to two bits of precision and then subtracted, which kills two bits of precision:
sage: N(pi, prec=2)
3.0
sage: N(3, prec=2)
3.0
sage: N(pi - 3, prec=2)
0.00
TESTS:
sage: numerical_approx(I)
1.00000000000000*I
sage: x = QQ['x'].gen()
sage: F.<k> = NumberField(x^2+2, embedding=sqrt(CC(2))*CC.0)
sage: numerical_approx(k)
1.41421356237309*I
sage: type(numerical_approx(CC(1/2)))
<type 'sage.rings.complex_number.ComplexNumber'>
The following tests trac ticket #10761, in which n() would break when called on complex-valued algebraic numbers.
sage: E = matrix(3, [3,1,6,5,2,9,7,3,13]).eigenvalues(); E
[18.16815365088822?, -0.08407682544410650? - 0.2190261484802906?*I, -0.08407682544410650? + 0.2190261484802906?*I]
sage: E[1].parent()
Algebraic Field
sage: [a.n() for a in E]
[18.1681536508882, -0.0840768254441065 - 0.219026148480291*I, -0.0840768254441065 + 0.219026148480291*I]
Make sure we’ve rounded up log(10,2) enough to guarantee sufficient precision (trac #10164):
sage: ks = 4*10**5, 10**6
sage: check_str_length = lambda k: len(str(numerical_approx(1+10**-k,digits=k+1)))-1 >= k+1
sage: check_precision = lambda k: numerical_approx(1+10**-k,digits=k+1)-1 > 0
sage: all(check_str_length(k) and check_precision(k) for k in ks)
True
Testing we have sufficient precision for the golden ratio (trac #12163), note that the decimal point adds 1 to the string length:
sage: len(str(n(golden_ratio, digits=5000))) 5001 sage: len(str(n(golden_ratio, digits=5000000))) # long time (4s on sage.math, 2012) 5000001
EXAMPLES:
sage: R, x = objgen(FractionField(QQ['x']))
sage: R
Fraction Field of Univariate Polynomial Ring in x over Rational Field
sage: x
x
EXAMPLES:
sage: R, x = objgens(PolynomialRing(QQ,3, 'x'))
sage: R
Multivariate Polynomial Ring in x0, x1, x2 over Rational Field
sage: x
(x0, x1, x2)
Returns the one element of the ring R.
EXAMPLES:
sage: R.<x> = PolynomialRing(QQ)
sage: one(R)*x == x
True
sage: one(R) in R
True
Returns the order of x. If x is a ring or module element, this is the additive order of x.
EXAMPLES:
sage: C = CyclicPermutationGroup(10)
sage: order(C)
10
sage: F = GF(7)
sage: order(F)
7
Returns x.parent() if defined, or type(x) if not.
EXAMPLE:
sage: Z = parent(int(5))
sage: Z(17)
17
sage: Z
<type 'int'>
Returns the quotient object x/y, e.g., a quotient of numbers or of a polynomial ring x by the ideal generated by y, etc.
EXAMPLES:
sage: quotient(5,6)
5/6
sage: quotient(5.,6.)
0.833333333333333
sage: R.<x> = ZZ[]; R
Univariate Polynomial Ring in x over Integer Ring
sage: I = Ideal(R, x^2+1)
sage: quotient(R, I)
Univariate Quotient Polynomial Ring in xbar over Integer Ring with modulus x^2 + 1
Returns the quotient object x/y, e.g., a quotient of numbers or of a polynomial ring x by the ideal generated by y, etc.
EXAMPLES:
sage: quotient(5,6)
5/6
sage: quotient(5.,6.)
0.833333333333333
sage: R.<x> = ZZ[]; R
Univariate Polynomial Ring in x over Integer Ring
sage: I = Ideal(R, x^2+1)
sage: quotient(R, I)
Univariate Quotient Polynomial Ring in xbar over Integer Ring with modulus x^2 + 1
Returns the rank of x.
EXAMPLES: We compute the rank of a matrix:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: rank(A)
2
We compute the rank of an elliptic curve:
sage: E = EllipticCurve([0,0,1,-1,0])
sage: rank(E)
1
Returns the regulator of x.
EXAMPLES:
sage: regulator(NumberField(x^2-2, 'a'))
0.881373587019543
sage: regulator(EllipticCurve('11a'))
1.00000000000000
round(number[, ndigits]) - double-precision real number
Round a number to a given precision in decimal digits (default 0 digits). If no precision is specified this just calls the element’s .round() method.
EXAMPLES:
sage: round(sqrt(2),2)
1.41
sage: q = round(sqrt(2),5); q
1.41421
sage: type(q)
<type 'sage.rings.real_double.RealDoubleElement'>
sage: q = round(sqrt(2)); q
1
sage: type(q)
<type 'sage.rings.integer.Integer'>
sage: round(pi)
3
sage: b = 5.4999999999999999
sage: round(b)
5
Since we use floating-point with a limited range, some roundings can’t be performed:
sage: round(sqrt(Integer('1'*1000)),2)
+infinity
IMPLEMENTATION: If ndigits is specified, it calls Python’s builtin round function, and converts the result to a real double field element. Otherwise, it tries the argument’s .round() method; if that fails, it reverts to the builtin round function, converted to a real double field element.
Note
This is currently slower than the builtin round function, since it does more work - i.e., allocating an RDF element and initializing it. To access the builtin version do import __builtin__; __builtin__.round.
Show a graphics object x.
For additional ways to show objects in the notebook, look at the methods on the html object. For example, html.table will produce an HTML table from a nested list.
OPTIONAL INPUT:
SOME OF THESE MAY APPLY:
EXAMPLES:
sage: show(graphs(3))
sage: show(list(graphs(3)))
Returns a square root of x.
This function (numerical_sqrt) is deprecated. Use sqrt(x, prec=n) instead.
EXAMPLES:
sage: numerical_sqrt(10.1)
doctest:1: DeprecationWarning: numerical_sqrt is deprecated, use sqrt(x, prec=n) instead
See http://trac.sagemath.org/5404 for details.
3.17804971641414
sage: numerical_sqrt(9)
3
Returns the square free part of , i.e., a divisor
such that
, for a perfect square
.
EXAMPLES:
sage: squarefree_part(100)
1
sage: squarefree_part(12)
3
sage: squarefree_part(10)
10
sage: squarefree_part(216r) # see #8976
6
sage: x = QQ['x'].0
sage: S = squarefree_part(-9*x*(x-6)^7*(x-3)^2); S
-9*x^2 + 54*x
sage: S.factor()
(-9) * (x - 6) * x
sage: f = (x^3 + x + 1)^3*(x-1); f
x^10 - x^9 + 3*x^8 + 3*x^5 - 2*x^4 - x^3 - 2*x - 1
sage: g = squarefree_part(f); g
x^4 - x^3 + x^2 - 1
sage: g.factor()
(x - 1) * (x^3 + x + 1)
Returns the symbolic sum with respect
to the variable
with endpoints
and
.
INPUT:
EXAMPLES:
sage: k, n = var('k,n')
sage: sum(k, k, 1, n).factor()
1/2*(n + 1)*n
sage: sum(1/k^4, k, 1, oo)
1/90*pi^4
sage: sum(1/k^5, k, 1, oo)
zeta(5)
A well known binomial identity:
sage: sum(binomial(n,k), k, 0, n)
2^n
The binomial theorem:
sage: x, y = var('x, y')
sage: sum(binomial(n,k) * x^k * y^(n-k), k, 0, n)
(x + y)^n
sage: sum(k * binomial(n, k), k, 1, n)
2^(n - 1)*n
sage: sum((-1)^k*binomial(n,k), k, 0, n)
0
sage: sum(2^(-k)/(k*(k+1)), k, 1, oo)
-log(2) + 1
Another binomial identity (trac #7952):
sage: t,k,i = var('t,k,i')
sage: sum(binomial(i+t,t),i,0,k)
binomial(k + t + 1, t + 1)
Summing a hypergeometric term:
sage: sum(binomial(n, k) * factorial(k) / factorial(n+1+k), k, 0, n)
1/2*sqrt(pi)/factorial(n + 1/2)
We check a well known identity:
sage: bool(sum(k^3, k, 1, n) == sum(k, k, 1, n)^2)
True
A geometric sum:
sage: a, q = var('a, q')
sage: sum(a*q^k, k, 0, n)
(a*q^(n + 1) - a)/(q - 1)
The geometric series:
sage: assume(abs(q) < 1)
sage: sum(a*q^k, k, 0, oo)
-a/(q - 1)
A divergent geometric series. Don’t forget to forget your assumptions:
sage: forget()
sage: assume(q > 1)
sage: sum(a*q^k, k, 0, oo)
Traceback (most recent call last):
...
ValueError: Sum is divergent.
This summation only Mathematica can perform:
sage: sum(1/(1+k^2), k, -oo, oo, algorithm = 'mathematica') # optional - mathematica
pi*coth(pi)
Use Maple as a backend for summation:
sage: sum(binomial(n,k)*x^k, k, 0, n, algorithm = 'maple') # optional - maple
(x + 1)^n
Python ints should work as limits of summation (trac #9393):
sage: sum(x, x, 1r, 5r)
15
Note
Returns the transpose of x.
EXAMPLES:
sage: M = MatrixSpace(QQ,3,3)
sage: A = M([1,2,3,4,5,6,7,8,9])
sage: transpose(A)
[1 4 7]
[2 5 8]
[3 6 9]
Iterator over the integers between a and b, inclusive.
EXAMPLES:
sage: I = xinterval(2,5); I
xrange(2, 6)
sage: 5 in I
True
sage: 6 in I
False
Returns the zero element of the ring R.
EXAMPLES:
sage: R.<x> = PolynomialRing(QQ)
sage: zero(R) in R
True
sage: zero(R)*x == zero(R)
True