Lazy Series Rings¶
We provide lazy implementations for various \(\NN\)-graded rings.
The ring of lazy Laurent series. |
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The ring of (possibly multivariate) lazy Taylor series. |
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The completion of a graded algebra consisting of formal series. |
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The ring of (possibly multivariate) lazy symmetric functions. |
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The ring of lazy Dirichlet series. |
Warning
When the halting precision is infinite, the default for bool(f)
is True
for any lazy series f
that is not known to be zero.
This could end up resulting in infinite loops:
sage: L.<x> = LazyPowerSeriesRing(ZZ)
sage: f = L(lambda n: 0, valuation=0)
sage: 1 / f # not tested - infinite loop
>>> from sage.all import *
>>> L = LazyPowerSeriesRing(ZZ, names=('x',)); (x,) = L._first_ngens(1)
>>> f = L(lambda n: Integer(0), valuation=Integer(0))
>>> Integer(1) / f # not tested - infinite loop
L.<x> = LazyPowerSeriesRing(ZZ) f = L(lambda n: 0, valuation=0) 1 / f # not tested - infinite loop
See also
The examples of LazyLaurentSeriesRing
contain a discussion
about the different methods of comparisons the lazy series can use.
AUTHORS:
Kwankyu Lee (2019-02-24): initial version
Tejasvi Chebrolu, Martin Rubey, Travis Scrimshaw (2021-08): refactored and expanded functionality
- class sage.rings.lazy_series_ring.LazyCompletionGradedAlgebra(basis, sparse=True, category=None)[source]¶
Bases:
LazySeriesRing
The completion of a graded algebra consisting of formal series.
For a graded algebra \(A\), we can form a completion of \(A\) consisting of all formal series of \(A\) such that each homogeneous component is a finite linear combination of basis elements of \(A\).
INPUT:
basis
– a graded algebranames
– name(s) of the alphabetssparse
– boolean (default:True
); whether we use a sparse or a dense representation
EXAMPLES:
sage: # needs sage.modules sage: NCSF = NonCommutativeSymmetricFunctions(QQ) sage: S = NCSF.Complete() sage: L = S.formal_series_ring(); L Lazy completion of Non-Commutative Symmetric Functions over the Rational Field in the Complete basis sage: f = 1 / (1 - L(S[1])); f S[] + S[1] + (S[1,1]) + (S[1,1,1]) + (S[1,1,1,1]) + (S[1,1,1,1,1]) + (S[1,1,1,1,1,1]) + O^7 sage: g = 1 / (1 - L(S[2])); g S[] + S[2] + (S[2,2]) + (S[2,2,2]) + O^7 sage: f * g S[] + S[1] + (S[1,1]+S[2]) + (S[1,1,1]+S[1,2]) + (S[1,1,1,1]+S[1,1,2]+S[2,2]) + (S[1,1,1,1,1]+S[1,1,1,2]+S[1,2,2]) + (S[1,1,1,1,1,1]+S[1,1,1,1,2]+S[1,1,2,2]+S[2,2,2]) + O^7 sage: g * f S[] + S[1] + (S[1,1]+S[2]) + (S[1,1,1]+S[2,1]) + (S[1,1,1,1]+S[2,1,1]+S[2,2]) + (S[1,1,1,1,1]+S[2,1,1,1]+S[2,2,1]) + (S[1,1,1,1,1,1]+S[2,1,1,1,1]+S[2,2,1,1]+S[2,2,2]) + O^7 sage: f * g - g * f (S[1,2]-S[2,1]) + (S[1,1,2]-S[2,1,1]) + (S[1,1,1,2]+S[1,2,2]-S[2,1,1,1]-S[2,2,1]) + (S[1,1,1,1,2]+S[1,1,2,2]-S[2,1,1,1,1]-S[2,2,1,1]) + O^7
>>> from sage.all import * >>> # needs sage.modules >>> NCSF = NonCommutativeSymmetricFunctions(QQ) >>> S = NCSF.Complete() >>> L = S.formal_series_ring(); L Lazy completion of Non-Commutative Symmetric Functions over the Rational Field in the Complete basis >>> f = Integer(1) / (Integer(1) - L(S[Integer(1)])); f S[] + S[1] + (S[1,1]) + (S[1,1,1]) + (S[1,1,1,1]) + (S[1,1,1,1,1]) + (S[1,1,1,1,1,1]) + O^7 >>> g = Integer(1) / (Integer(1) - L(S[Integer(2)])); g S[] + S[2] + (S[2,2]) + (S[2,2,2]) + O^7 >>> f * g S[] + S[1] + (S[1,1]+S[2]) + (S[1,1,1]+S[1,2]) + (S[1,1,1,1]+S[1,1,2]+S[2,2]) + (S[1,1,1,1,1]+S[1,1,1,2]+S[1,2,2]) + (S[1,1,1,1,1,1]+S[1,1,1,1,2]+S[1,1,2,2]+S[2,2,2]) + O^7 >>> g * f S[] + S[1] + (S[1,1]+S[2]) + (S[1,1,1]+S[2,1]) + (S[1,1,1,1]+S[2,1,1]+S[2,2]) + (S[1,1,1,1,1]+S[2,1,1,1]+S[2,2,1]) + (S[1,1,1,1,1,1]+S[2,1,1,1,1]+S[2,2,1,1]+S[2,2,2]) + O^7 >>> f * g - g * f (S[1,2]-S[2,1]) + (S[1,1,2]-S[2,1,1]) + (S[1,1,1,2]+S[1,2,2]-S[2,1,1,1]-S[2,2,1]) + (S[1,1,1,1,2]+S[1,1,2,2]-S[2,1,1,1,1]-S[2,2,1,1]) + O^7
# needs sage.modules NCSF = NonCommutativeSymmetricFunctions(QQ) S = NCSF.Complete() L = S.formal_series_ring(); L f = 1 / (1 - L(S[1])); f g = 1 / (1 - L(S[2])); g f * g g * f f * g - g * f
- Element[source]¶
alias of
LazyCompletionGradedAlgebraElement
- some_elements()[source]¶
Return a list of elements of
self
.EXAMPLES:
sage: m = SymmetricFunctions(GF(5)).m() # needs sage.modules sage: L = LazySymmetricFunctions(m) # needs sage.modules sage: L.some_elements()[:5] # needs sage.modules [0, m[], 2*m[] + 2*m[1] + 3*m[2], 2*m[1] + 3*m[2], 3*m[] + 2*m[1] + (m[1,1]+m[2]) + (2*m[1,1,1]+m[3]) + (2*m[1,1,1,1]+4*m[2,1,1]+2*m[2,2]) + (3*m[2,1,1,1]+3*m[3,1,1]+4*m[3,2]+m[5]) + (2*m[2,2,1,1]+m[2,2,2]+2*m[3,2,1]+2*m[3,3]+m[4,1,1]+3*m[4,2]+4*m[5,1]+4*m[6]) + O^7] sage: # needs sage.modules sage: NCSF = NonCommutativeSymmetricFunctions(QQ) sage: S = NCSF.Complete() sage: L = S.formal_series_ring() sage: L.some_elements()[:4] [0, S[], 2*S[] + 2*S[1] + (3*S[1,1]), 2*S[1] + (3*S[1,1])]
>>> from sage.all import * >>> m = SymmetricFunctions(GF(Integer(5))).m() # needs sage.modules >>> L = LazySymmetricFunctions(m) # needs sage.modules >>> L.some_elements()[:Integer(5)] # needs sage.modules [0, m[], 2*m[] + 2*m[1] + 3*m[2], 2*m[1] + 3*m[2], 3*m[] + 2*m[1] + (m[1,1]+m[2]) + (2*m[1,1,1]+m[3]) + (2*m[1,1,1,1]+4*m[2,1,1]+2*m[2,2]) + (3*m[2,1,1,1]+3*m[3,1,1]+4*m[3,2]+m[5]) + (2*m[2,2,1,1]+m[2,2,2]+2*m[3,2,1]+2*m[3,3]+m[4,1,1]+3*m[4,2]+4*m[5,1]+4*m[6]) + O^7] >>> # needs sage.modules >>> NCSF = NonCommutativeSymmetricFunctions(QQ) >>> S = NCSF.Complete() >>> L = S.formal_series_ring() >>> L.some_elements()[:Integer(4)] [0, S[], 2*S[] + 2*S[1] + (3*S[1,1]), 2*S[1] + (3*S[1,1])]
m = SymmetricFunctions(GF(5)).m() # needs sage.modules L = LazySymmetricFunctions(m) # needs sage.modules L.some_elements()[:5] # needs sage.modules # needs sage.modules NCSF = NonCommutativeSymmetricFunctions(QQ) S = NCSF.Complete() L = S.formal_series_ring() L.some_elements()[:4]
- class sage.rings.lazy_series_ring.LazyDirichletSeriesRing(base_ring, names, sparse=True, category=None)[source]¶
Bases:
LazySeriesRing
The ring of lazy Dirichlet series.
INPUT:
base_ring
– base ring of this Dirichlet series ringnames
– name of the generator of this Dirichlet series ringsparse
– boolean (default:True
); whether this series is sparse or not
Unlike formal univariate Laurent/power series (over a field), the ring of formal Dirichlet series is not a Wikipedia article discrete_valuation_ring. On the other hand, it is a Wikipedia article local_ring. The unique maximal ideal consists of all non-invertible series, i.e., series with vanishing constant term.
Todo
According to the answers in https://mathoverflow.net/questions/5522/dirichlet-series-with-integer-coefficients-as-a-ufd, (which, in particular, references arXiv math/0105219) the ring of formal Dirichlet series is actually a Wikipedia article Unique_factorization_domain over \(\ZZ\).
Note
An interesting valuation is described in Emil Daniel Schwab; Gheorghe Silberberg A note on some discrete valuation rings of arithmetical functions, Archivum Mathematicum, Vol. 36 (2000), No. 2, 103-109, http://dml.cz/dmlcz/107723. Let \(J_k\) be the ideal of Dirichlet series whose coefficient \(f[n]\) of \(n^s\) vanishes if \(n\) has less than \(k\) prime factors, counting multiplicities. For any Dirichlet series \(f\), let \(D(f)\) be the largest integer \(k\) such that \(f\) is in \(J_k\). Then \(D\) is surjective, \(D(f g) = D(f) + D(g)\) for nonzero \(f\) and \(g\), and \(D(f + g) \geq \min(D(f), D(g))\) provided that \(f + g\) is nonzero.
For example, \(J_1\) are series with no constant term, and \(J_2\) are series such that \(f[1]\) and \(f[p]\) for prime \(p\) vanish.
Since this is a chain of increasing ideals, the ring of formal Dirichlet series is not a Wikipedia article Noetherian_ring.
Evidently, this valuation cannot be computed for a given series.
EXAMPLES:
sage: LazyDirichletSeriesRing(ZZ, 't') Lazy Dirichlet Series Ring in t over Integer Ring
>>> from sage.all import * >>> LazyDirichletSeriesRing(ZZ, 't') Lazy Dirichlet Series Ring in t over Integer Ring
LazyDirichletSeriesRing(ZZ, 't')
The ideal generated by \(2^-s\) and \(3^-s\) is not principal:
sage: L = LazyDirichletSeriesRing(QQ, 's') sage: L in PrincipalIdealDomains False
>>> from sage.all import * >>> L = LazyDirichletSeriesRing(QQ, 's') >>> L in PrincipalIdealDomains False
L = LazyDirichletSeriesRing(QQ, 's') L in PrincipalIdealDomains
- Element[source]¶
alias of
LazyDirichletSeries
- one()[source]¶
Return the constant series \(1\).
EXAMPLES:
sage: L = LazyDirichletSeriesRing(ZZ, 'z') sage: L.one() # needs sage.symbolic 1 sage: ~L.one() # needs sage.symbolic 1 + O(1/(8^z))
>>> from sage.all import * >>> L = LazyDirichletSeriesRing(ZZ, 'z') >>> L.one() # needs sage.symbolic 1 >>> ~L.one() # needs sage.symbolic 1 + O(1/(8^z))
L = LazyDirichletSeriesRing(ZZ, 'z') L.one() # needs sage.symbolic ~L.one() # needs sage.symbolic
- some_elements()[source]¶
Return a list of elements of
self
.EXAMPLES:
sage: L = LazyDirichletSeriesRing(ZZ, 'z') sage: l = L.some_elements() sage: l # needs sage.symbolic [0, 1, 1/(4^z) + 1/(5^z) + 1/(6^z) + O(1/(7^z)), 1/(2^z) - 1/(3^z) + 2/4^z - 2/5^z + 3/6^z - 3/7^z + 4/8^z - 4/9^z, 1/(2^z) - 1/(3^z) + 2/4^z - 2/5^z + 3/6^z - 3/7^z + 4/8^z - 4/9^z + 1/(10^z) + 1/(11^z) + 1/(12^z) + O(1/(13^z)), 1 + 4/2^z + 9/3^z + 16/4^z + 25/5^z + 36/6^z + 49/7^z + O(1/(8^z))] sage: L = LazyDirichletSeriesRing(QQ, 'z') sage: l = L.some_elements() sage: l # needs sage.symbolic [0, 1, 1/2/4^z + 1/2/5^z + 1/2/6^z + O(1/(7^z)), 1/2 - 1/2/2^z + 2/3^z - 2/4^z + 1/(6^z) - 1/(7^z) + 42/8^z + 2/3/9^z, 1/2 - 1/2/2^z + 2/3^z - 2/4^z + 1/(6^z) - 1/(7^z) + 42/8^z + 2/3/9^z + 1/2/10^z + 1/2/11^z + 1/2/12^z + O(1/(13^z)), 1 + 4/2^z + 9/3^z + 16/4^z + 25/5^z + 36/6^z + 49/7^z + O(1/(8^z))]
>>> from sage.all import * >>> L = LazyDirichletSeriesRing(ZZ, 'z') >>> l = L.some_elements() >>> l # needs sage.symbolic [0, 1, 1/(4^z) + 1/(5^z) + 1/(6^z) + O(1/(7^z)), 1/(2^z) - 1/(3^z) + 2/4^z - 2/5^z + 3/6^z - 3/7^z + 4/8^z - 4/9^z, 1/(2^z) - 1/(3^z) + 2/4^z - 2/5^z + 3/6^z - 3/7^z + 4/8^z - 4/9^z + 1/(10^z) + 1/(11^z) + 1/(12^z) + O(1/(13^z)), 1 + 4/2^z + 9/3^z + 16/4^z + 25/5^z + 36/6^z + 49/7^z + O(1/(8^z))] >>> L = LazyDirichletSeriesRing(QQ, 'z') >>> l = L.some_elements() >>> l # needs sage.symbolic [0, 1, 1/2/4^z + 1/2/5^z + 1/2/6^z + O(1/(7^z)), 1/2 - 1/2/2^z + 2/3^z - 2/4^z + 1/(6^z) - 1/(7^z) + 42/8^z + 2/3/9^z, 1/2 - 1/2/2^z + 2/3^z - 2/4^z + 1/(6^z) - 1/(7^z) + 42/8^z + 2/3/9^z + 1/2/10^z + 1/2/11^z + 1/2/12^z + O(1/(13^z)), 1 + 4/2^z + 9/3^z + 16/4^z + 25/5^z + 36/6^z + 49/7^z + O(1/(8^z))]
L = LazyDirichletSeriesRing(ZZ, 'z') l = L.some_elements() l # needs sage.symbolic L = LazyDirichletSeriesRing(QQ, 'z') l = L.some_elements() l # needs sage.symbolic
- class sage.rings.lazy_series_ring.LazyLaurentSeriesRing(base_ring, names, sparse=True, category=None)[source]¶
Bases:
LazySeriesRing
The ring of lazy Laurent series.
The ring of Laurent series over a ring with the usual arithmetic where the coefficients are computed lazily.
INPUT:
base_ring
– base ringnames
– name of the generatorsparse
– boolean (default:True
); whether the implementation of the series is sparse or not
EXAMPLES:
sage: L.<z> = LazyLaurentSeriesRing(QQ) sage: 1 / (1 - z) 1 + z + z^2 + O(z^3) sage: 1 / (1 - z) == 1 / (1 - z) True sage: L in Fields True
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> Integer(1) / (Integer(1) - z) 1 + z + z^2 + O(z^3) >>> Integer(1) / (Integer(1) - z) == Integer(1) / (Integer(1) - z) True >>> L in Fields True
L.<z> = LazyLaurentSeriesRing(QQ) 1 / (1 - z) 1 / (1 - z) == 1 / (1 - z) L in Fields
Lazy Laurent series ring over a finite field:
sage: # needs sage.rings.finite_rings sage: L.<z> = LazyLaurentSeriesRing(GF(3)); L Lazy Laurent Series Ring in z over Finite Field of size 3 sage: e = 1 / (1 + z) sage: e.coefficient(100) 1 sage: e.coefficient(100).parent() Finite Field of size 3
>>> from sage.all import * >>> # needs sage.rings.finite_rings >>> L = LazyLaurentSeriesRing(GF(Integer(3)), names=('z',)); (z,) = L._first_ngens(1); L Lazy Laurent Series Ring in z over Finite Field of size 3 >>> e = Integer(1) / (Integer(1) + z) >>> e.coefficient(Integer(100)) 1 >>> e.coefficient(Integer(100)).parent() Finite Field of size 3
# needs sage.rings.finite_rings L.<z> = LazyLaurentSeriesRing(GF(3)); L e = 1 / (1 + z) e.coefficient(100) e.coefficient(100).parent()
Series can be defined by specifying a coefficient function and a valuation:
sage: R.<x,y> = QQ[] sage: L.<z> = LazyLaurentSeriesRing(R) sage: def coeff(n): ....: if n < 0: ....: return -2 + n ....: if n == 0: ....: return 6 ....: return x + y^n sage: f = L(coeff, valuation=-5) sage: f -7*z^-5 - 6*z^-4 - 5*z^-3 - 4*z^-2 - 3*z^-1 + 6 + (x + y)*z + O(z^2) sage: 1 / (1 - f) 1/7*z^5 - 6/49*z^6 + 1/343*z^7 + 8/2401*z^8 + 64/16807*z^9 + 17319/117649*z^10 + (1/49*x + 1/49*y - 180781/823543)*z^11 + O(z^12) sage: L(coeff, valuation=-3, degree=3, constant=x) -5*z^-3 - 4*z^-2 - 3*z^-1 + 6 + (x + y)*z + (y^2 + x)*z^2 + x*z^3 + x*z^4 + x*z^5 + O(z^6)
>>> from sage.all import * >>> R = QQ['x, y']; (x, y,) = R._first_ngens(2) >>> L = LazyLaurentSeriesRing(R, names=('z',)); (z,) = L._first_ngens(1) >>> def coeff(n): ... if n < Integer(0): ... return -Integer(2) + n ... if n == Integer(0): ... return Integer(6) ... return x + y**n >>> f = L(coeff, valuation=-Integer(5)) >>> f -7*z^-5 - 6*z^-4 - 5*z^-3 - 4*z^-2 - 3*z^-1 + 6 + (x + y)*z + O(z^2) >>> Integer(1) / (Integer(1) - f) 1/7*z^5 - 6/49*z^6 + 1/343*z^7 + 8/2401*z^8 + 64/16807*z^9 + 17319/117649*z^10 + (1/49*x + 1/49*y - 180781/823543)*z^11 + O(z^12) >>> L(coeff, valuation=-Integer(3), degree=Integer(3), constant=x) -5*z^-3 - 4*z^-2 - 3*z^-1 + 6 + (x + y)*z + (y^2 + x)*z^2 + x*z^3 + x*z^4 + x*z^5 + O(z^6)
R.<x,y> = QQ[] L.<z> = LazyLaurentSeriesRing(R) def coeff(n): if n < 0: return -2 + n if n == 0: return 6 return x + y^n f = L(coeff, valuation=-5) f 1 / (1 - f) L(coeff, valuation=-3, degree=3, constant=x)
We can also specify a polynomial or the initial coefficients. Additionally, we may specify that all coefficients are equal to a given constant, beginning at a given degree:
sage: L([1, x, y, 0, x+y]) 1 + x*z + y*z^2 + (x + y)*z^4 sage: L([1, x, y, 0, x+y], constant=2) 1 + x*z + y*z^2 + (x + y)*z^4 + 2*z^5 + 2*z^6 + 2*z^7 + O(z^8) sage: L([1, x, y, 0, x+y], degree=7, constant=2) 1 + x*z + y*z^2 + (x + y)*z^4 + 2*z^7 + 2*z^8 + 2*z^9 + O(z^10) sage: L([1, x, y, 0, x+y], valuation=-2) z^-2 + x*z^-1 + y + (x + y)*z^2 sage: L([1, x, y, 0, x+y], valuation=-2, constant=3) z^-2 + x*z^-1 + y + (x + y)*z^2 + 3*z^3 + 3*z^4 + 3*z^5 + O(z^6) sage: L([1, x, y, 0, x+y], valuation=-2, degree=4, constant=3) z^-2 + x*z^-1 + y + (x + y)*z^2 + 3*z^4 + 3*z^5 + 3*z^6 + O(z^7)
>>> from sage.all import * >>> L([Integer(1), x, y, Integer(0), x+y]) 1 + x*z + y*z^2 + (x + y)*z^4 >>> L([Integer(1), x, y, Integer(0), x+y], constant=Integer(2)) 1 + x*z + y*z^2 + (x + y)*z^4 + 2*z^5 + 2*z^6 + 2*z^7 + O(z^8) >>> L([Integer(1), x, y, Integer(0), x+y], degree=Integer(7), constant=Integer(2)) 1 + x*z + y*z^2 + (x + y)*z^4 + 2*z^7 + 2*z^8 + 2*z^9 + O(z^10) >>> L([Integer(1), x, y, Integer(0), x+y], valuation=-Integer(2)) z^-2 + x*z^-1 + y + (x + y)*z^2 >>> L([Integer(1), x, y, Integer(0), x+y], valuation=-Integer(2), constant=Integer(3)) z^-2 + x*z^-1 + y + (x + y)*z^2 + 3*z^3 + 3*z^4 + 3*z^5 + O(z^6) >>> L([Integer(1), x, y, Integer(0), x+y], valuation=-Integer(2), degree=Integer(4), constant=Integer(3)) z^-2 + x*z^-1 + y + (x + y)*z^2 + 3*z^4 + 3*z^5 + 3*z^6 + O(z^7)
L([1, x, y, 0, x+y]) L([1, x, y, 0, x+y], constant=2) L([1, x, y, 0, x+y], degree=7, constant=2) L([1, x, y, 0, x+y], valuation=-2) L([1, x, y, 0, x+y], valuation=-2, constant=3) L([1, x, y, 0, x+y], valuation=-2, degree=4, constant=3)
Some additional examples over the integer ring:
sage: L.<z> = LazyLaurentSeriesRing(ZZ) sage: L in Fields False sage: 1 / (1 - 2*z)^3 1 + 6*z + 24*z^2 + 80*z^3 + 240*z^4 + 672*z^5 + 1792*z^6 + O(z^7) sage: R.<x> = LaurentPolynomialRing(ZZ) sage: L(x^-2 + 3 + x) z^-2 + 3 + z sage: L(x^-2 + 3 + x, valuation=-5, constant=2) z^-5 + 3*z^-3 + z^-2 + 2*z^-1 + 2 + 2*z + O(z^2) sage: L(x^-2 + 3 + x, valuation=-5, degree=0, constant=2) z^-5 + 3*z^-3 + z^-2 + 2 + 2*z + 2*z^2 + O(z^3)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> L in Fields False >>> Integer(1) / (Integer(1) - Integer(2)*z)**Integer(3) 1 + 6*z + 24*z^2 + 80*z^3 + 240*z^4 + 672*z^5 + 1792*z^6 + O(z^7) >>> R = LaurentPolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> L(x**-Integer(2) + Integer(3) + x) z^-2 + 3 + z >>> L(x**-Integer(2) + Integer(3) + x, valuation=-Integer(5), constant=Integer(2)) z^-5 + 3*z^-3 + z^-2 + 2*z^-1 + 2 + 2*z + O(z^2) >>> L(x**-Integer(2) + Integer(3) + x, valuation=-Integer(5), degree=Integer(0), constant=Integer(2)) z^-5 + 3*z^-3 + z^-2 + 2 + 2*z + 2*z^2 + O(z^3)
L.<z> = LazyLaurentSeriesRing(ZZ) L in Fields 1 / (1 - 2*z)^3 R.<x> = LaurentPolynomialRing(ZZ) L(x^-2 + 3 + x) L(x^-2 + 3 + x, valuation=-5, constant=2) L(x^-2 + 3 + x, valuation=-5, degree=0, constant=2)
We can truncate a series, shift its coefficients, or replace all coefficients beginning with a given degree by a constant:
sage: f = 1 / (z + z^2) sage: f z^-1 - 1 + z - z^2 + z^3 - z^4 + z^5 + O(z^6) sage: L(f, valuation=2) z^2 - z^3 + z^4 - z^5 + z^6 - z^7 + z^8 + O(z^9) sage: L(f, degree=3) z^-1 - 1 + z - z^2 sage: L(f, degree=3, constant=2) z^-1 - 1 + z - z^2 + 2*z^3 + 2*z^4 + 2*z^5 + O(z^6) sage: L(f, valuation=1, degree=4) z - z^2 + z^3 sage: L(f, valuation=1, degree=4, constant=5) z - z^2 + z^3 + 5*z^4 + 5*z^5 + 5*z^6 + O(z^7)
>>> from sage.all import * >>> f = Integer(1) / (z + z**Integer(2)) >>> f z^-1 - 1 + z - z^2 + z^3 - z^4 + z^5 + O(z^6) >>> L(f, valuation=Integer(2)) z^2 - z^3 + z^4 - z^5 + z^6 - z^7 + z^8 + O(z^9) >>> L(f, degree=Integer(3)) z^-1 - 1 + z - z^2 >>> L(f, degree=Integer(3), constant=Integer(2)) z^-1 - 1 + z - z^2 + 2*z^3 + 2*z^4 + 2*z^5 + O(z^6) >>> L(f, valuation=Integer(1), degree=Integer(4)) z - z^2 + z^3 >>> L(f, valuation=Integer(1), degree=Integer(4), constant=Integer(5)) z - z^2 + z^3 + 5*z^4 + 5*z^5 + 5*z^6 + O(z^7)
f = 1 / (z + z^2) f L(f, valuation=2) L(f, degree=3) L(f, degree=3, constant=2) L(f, valuation=1, degree=4) L(f, valuation=1, degree=4, constant=5)
Power series can be defined recursively (see
sage.rings.lazy_series.LazyModuleElement.define()
for more examples):sage: L.<z> = LazyLaurentSeriesRing(ZZ) sage: s = L.undefined(valuation=0) sage: s.define(1 + z*s^2) sage: s 1 + z + 2*z^2 + 5*z^3 + 14*z^4 + 42*z^5 + 132*z^6 + O(z^7)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> s = L.undefined(valuation=Integer(0)) >>> s.define(Integer(1) + z*s**Integer(2)) >>> s 1 + z + 2*z^2 + 5*z^3 + 14*z^4 + 42*z^5 + 132*z^6 + O(z^7)
L.<z> = LazyLaurentSeriesRing(ZZ) s = L.undefined(valuation=0) s.define(1 + z*s^2) s
By default, any two series
f
andg
that are not known to be equal are considered to be different:sage: f = L(lambda n: 0, valuation=0) sage: f == 0 False sage: f = L(constant=1, valuation=0).derivative(); f 1 + 2*z + 3*z^2 + 4*z^3 + 5*z^4 + 6*z^5 + 7*z^6 + O(z^7) sage: g = L(lambda n: (n+1), valuation=0); g 1 + 2*z + 3*z^2 + 4*z^3 + 5*z^4 + 6*z^5 + 7*z^6 + O(z^7) sage: f == g False
>>> from sage.all import * >>> f = L(lambda n: Integer(0), valuation=Integer(0)) >>> f == Integer(0) False >>> f = L(constant=Integer(1), valuation=Integer(0)).derivative(); f 1 + 2*z + 3*z^2 + 4*z^3 + 5*z^4 + 6*z^5 + 7*z^6 + O(z^7) >>> g = L(lambda n: (n+Integer(1)), valuation=Integer(0)); g 1 + 2*z + 3*z^2 + 4*z^3 + 5*z^4 + 6*z^5 + 7*z^6 + O(z^7) >>> f == g False
f = L(lambda n: 0, valuation=0) f == 0 f = L(constant=1, valuation=0).derivative(); f g = L(lambda n: (n+1), valuation=0); g f == g
Warning
We have imposed that
(f == g) == not (f != g)
, and sof != g
returningTrue
might not mean that the two series are actually different:sage: f = L(lambda n: 0, valuation=0) sage: g = L.zero() sage: f != g True
>>> from sage.all import * >>> f = L(lambda n: Integer(0), valuation=Integer(0)) >>> g = L.zero() >>> f != g True
f = L(lambda n: 0, valuation=0) g = L.zero() f != g
This can be verified by
is_nonzero()
, which only returnsTrue
if the series is known to be nonzero:sage: (f - g).is_nonzero() False
>>> from sage.all import * >>> (f - g).is_nonzero() False
(f - g).is_nonzero()
The implementation of the ring can be either be a sparse or a dense one. The default is a sparse implementation:
sage: L.<z> = LazyLaurentSeriesRing(ZZ) sage: L.is_sparse() True sage: L.<z> = LazyLaurentSeriesRing(ZZ, sparse=False) sage: L.is_sparse() False
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> L.is_sparse() True >>> L = LazyLaurentSeriesRing(ZZ, sparse=False, names=('z',)); (z,) = L._first_ngens(1) >>> L.is_sparse() False
L.<z> = LazyLaurentSeriesRing(ZZ) L.is_sparse() L.<z> = LazyLaurentSeriesRing(ZZ, sparse=False) L.is_sparse()
We additionally provide two other methods of performing comparisons. The first is raising a
ValueError
and the second uses a check up to a (user set) finite precision. These behaviors are set using the optionssecure
andhalting_precision
. In particular, this applies to series that are not specified by a finite number of initial coefficients and a constant for the remaining coefficients. Equality checking will depend on the coefficients which have already been computed. If this information is not enough to check that two series are different, then ifL.options.secure
is set toTrue
, then we raise aValueError
:sage: L.options.secure = True sage: f = 1 / (z + z^2); f z^-1 - 1 + z - z^2 + z^3 - z^4 + z^5 + O(z^6) sage: f2 = f * 2 # currently no coefficients computed sage: f3 = f * 3 # currently no coefficients computed sage: f2 == f3 Traceback (most recent call last): ... ValueError: undecidable sage: f2 # computes some of the coefficients of f2 2*z^-1 - 2 + 2*z - 2*z^2 + 2*z^3 - 2*z^4 + 2*z^5 + O(z^6) sage: f3 # computes some of the coefficients of f3 3*z^-1 - 3 + 3*z - 3*z^2 + 3*z^3 - 3*z^4 + 3*z^5 + O(z^6) sage: f2 == f3 False sage: f2a = f + f sage: f2 == f2a Traceback (most recent call last): ... ValueError: undecidable sage: zf = L(lambda n: 0, valuation=0) sage: zf == 0 Traceback (most recent call last): ... ValueError: undecidable
>>> from sage.all import * >>> L.options.secure = True >>> f = Integer(1) / (z + z**Integer(2)); f z^-1 - 1 + z - z^2 + z^3 - z^4 + z^5 + O(z^6) >>> f2 = f * Integer(2) # currently no coefficients computed >>> f3 = f * Integer(3) # currently no coefficients computed >>> f2 == f3 Traceback (most recent call last): ... ValueError: undecidable >>> f2 # computes some of the coefficients of f2 2*z^-1 - 2 + 2*z - 2*z^2 + 2*z^3 - 2*z^4 + 2*z^5 + O(z^6) >>> f3 # computes some of the coefficients of f3 3*z^-1 - 3 + 3*z - 3*z^2 + 3*z^3 - 3*z^4 + 3*z^5 + O(z^6) >>> f2 == f3 False >>> f2a = f + f >>> f2 == f2a Traceback (most recent call last): ... ValueError: undecidable >>> zf = L(lambda n: Integer(0), valuation=Integer(0)) >>> zf == Integer(0) Traceback (most recent call last): ... ValueError: undecidable
L.options.secure = True f = 1 / (z + z^2); f f2 = f * 2 # currently no coefficients computed f3 = f * 3 # currently no coefficients computed f2 == f3 f2 # computes some of the coefficients of f2 f3 # computes some of the coefficients of f3 f2 == f3 f2a = f + f f2 == f2a zf = L(lambda n: 0, valuation=0) zf == 0
For boolean checks, an error is raised when it is not known to be nonzero:
sage: bool(zf) Traceback (most recent call last): ... ValueError: undecidable
>>> from sage.all import * >>> bool(zf) Traceback (most recent call last): ... ValueError: undecidable
bool(zf)
If the halting precision is set to a finite number \(p\) (for unlimited precision, it is set to
None
), then it will check up to \(p\) values from the current position:sage: L.options.halting_precision = 20 sage: f2 = f * 2 # currently no coefficients computed sage: f3 = f * 3 # currently no coefficients computed sage: f2 == f3 False sage: f2a = f + f sage: f2 == f2a True sage: zf = L(lambda n: 0, valuation=0) sage: zf == 0 True
>>> from sage.all import * >>> L.options.halting_precision = Integer(20) >>> f2 = f * Integer(2) # currently no coefficients computed >>> f3 = f * Integer(3) # currently no coefficients computed >>> f2 == f3 False >>> f2a = f + f >>> f2 == f2a True >>> zf = L(lambda n: Integer(0), valuation=Integer(0)) >>> zf == Integer(0) True
L.options.halting_precision = 20 f2 = f * 2 # currently no coefficients computed f3 = f * 3 # currently no coefficients computed f2 == f3 f2a = f + f f2 == f2a zf = L(lambda n: 0, valuation=0) zf == 0
- Element[source]¶
alias of
LazyLaurentSeries
- euler()[source]¶
Return the Euler function as an element of
self
.The Euler function is defined as
\[\phi(z) = (z; z)_{\infty} = \sum_{n=0}^{\infty} (-1)^n q^{(3n^2-n)/2}.\]EXAMPLES:
sage: L.<q> = LazyLaurentSeriesRing(ZZ) sage: phi = q.euler() sage: phi 1 - q - q^2 + q^5 + O(q^7)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('q',)); (q,) = L._first_ngens(1) >>> phi = q.euler() >>> phi 1 - q - q^2 + q^5 + O(q^7)
L.<q> = LazyLaurentSeriesRing(ZZ) phi = q.euler() phi
We verify that \(1 / phi\) gives the generating function for all partitions:
sage: P = 1 / phi; P 1 + q + 2*q^2 + 3*q^3 + 5*q^4 + 7*q^5 + 11*q^6 + O(q^7) sage: P[:20] == [Partitions(n).cardinality() for n in range(20)] # needs sage.libs.flint True
>>> from sage.all import * >>> P = Integer(1) / phi; P 1 + q + 2*q^2 + 3*q^3 + 5*q^4 + 7*q^5 + 11*q^6 + O(q^7) >>> P[:Integer(20)] == [Partitions(n).cardinality() for n in range(Integer(20))] # needs sage.libs.flint True
P = 1 / phi; P P[:20] == [Partitions(n).cardinality() for n in range(20)] # needs sage.libs.flint
REFERENCES:
- gen(n=0)[source]¶
Return the
n
-th generator ofself
.EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.gen() z sage: L.gen(3) Traceback (most recent call last): ... IndexError: there is only one generator
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.gen() z >>> L.gen(Integer(3)) Traceback (most recent call last): ... IndexError: there is only one generator
L = LazyLaurentSeriesRing(ZZ, 'z') L.gen() L.gen(3)
- gens()[source]¶
Return the generators of
self
.EXAMPLES:
sage: L.<z> = LazyLaurentSeriesRing(ZZ) sage: L.gens() (z,) sage: 1/(1 - z) 1 + z + z^2 + O(z^3)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> L.gens() (z,) >>> Integer(1)/(Integer(1) - z) 1 + z + z^2 + O(z^3)
L.<z> = LazyLaurentSeriesRing(ZZ) L.gens() 1/(1 - z)
- ngens()[source]¶
Return the number of generators of
self
.This is always 1.
EXAMPLES:
sage: L.<z> = LazyLaurentSeriesRing(ZZ) sage: L.ngens() 1
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> L.ngens() 1
L.<z> = LazyLaurentSeriesRing(ZZ) L.ngens()
- q_pochhammer(q=None)[source]¶
Return the infinite
q
-Pochhammer symbol \((a; q)_{\infty}\), where \(a\) is the variable ofself
.This is also one version of the quantum dilogarithm or the \(q\)-Exponential function.
INPUT:
q
– (default: \(q \in \QQ(q)\)) the parameter \(q\)
EXAMPLES:
sage: q = ZZ['q'].fraction_field().gen() sage: L.<z> = LazyLaurentSeriesRing(q.parent()) sage: qpoch = L.q_pochhammer(q) sage: qpoch 1 + (-1/(-q + 1))*z + (q/(q^3 - q^2 - q + 1))*z^2 + (-q^3/(-q^6 + q^5 + q^4 - q^2 - q + 1))*z^3 + (q^6/(q^10 - q^9 - q^8 + 2*q^5 - q^2 - q + 1))*z^4 + (-q^10/(-q^15 + q^14 + q^13 - q^10 - q^9 - q^8 + q^7 + q^6 + q^5 - q^2 - q + 1))*z^5 + (q^15/(q^21 - q^20 - q^19 + q^16 + 2*q^14 - q^12 - q^11 - q^10 - q^9 + 2*q^7 + q^5 - q^2 - q + 1))*z^6 + O(z^7)
>>> from sage.all import * >>> q = ZZ['q'].fraction_field().gen() >>> L = LazyLaurentSeriesRing(q.parent(), names=('z',)); (z,) = L._first_ngens(1) >>> qpoch = L.q_pochhammer(q) >>> qpoch 1 + (-1/(-q + 1))*z + (q/(q^3 - q^2 - q + 1))*z^2 + (-q^3/(-q^6 + q^5 + q^4 - q^2 - q + 1))*z^3 + (q^6/(q^10 - q^9 - q^8 + 2*q^5 - q^2 - q + 1))*z^4 + (-q^10/(-q^15 + q^14 + q^13 - q^10 - q^9 - q^8 + q^7 + q^6 + q^5 - q^2 - q + 1))*z^5 + (q^15/(q^21 - q^20 - q^19 + q^16 + 2*q^14 - q^12 - q^11 - q^10 - q^9 + 2*q^7 + q^5 - q^2 - q + 1))*z^6 + O(z^7)
q = ZZ['q'].fraction_field().gen() L.<z> = LazyLaurentSeriesRing(q.parent()) qpoch = L.q_pochhammer(q) qpoch
We show that \((z; q)_n = \frac{(z; q)_{\infty}}{(q^n z; q)_{\infty}}\):
sage: qpoch / qpoch(q*z) 1 - z + O(z^7) sage: qpoch / qpoch(q^2*z) 1 + (-q - 1)*z + q*z^2 + O(z^7) sage: qpoch / qpoch(q^3*z) 1 + (-q^2 - q - 1)*z + (q^3 + q^2 + q)*z^2 - q^3*z^3 + O(z^7) sage: qpoch / qpoch(q^4*z) 1 + (-q^3 - q^2 - q - 1)*z + (q^5 + q^4 + 2*q^3 + q^2 + q)*z^2 + (-q^6 - q^5 - q^4 - q^3)*z^3 + q^6*z^4 + O(z^7)
>>> from sage.all import * >>> qpoch / qpoch(q*z) 1 - z + O(z^7) >>> qpoch / qpoch(q**Integer(2)*z) 1 + (-q - 1)*z + q*z^2 + O(z^7) >>> qpoch / qpoch(q**Integer(3)*z) 1 + (-q^2 - q - 1)*z + (q^3 + q^2 + q)*z^2 - q^3*z^3 + O(z^7) >>> qpoch / qpoch(q**Integer(4)*z) 1 + (-q^3 - q^2 - q - 1)*z + (q^5 + q^4 + 2*q^3 + q^2 + q)*z^2 + (-q^6 - q^5 - q^4 - q^3)*z^3 + q^6*z^4 + O(z^7)
qpoch / qpoch(q*z) qpoch / qpoch(q^2*z) qpoch / qpoch(q^3*z) qpoch / qpoch(q^4*z)
We can also construct part of Euler’s function:
sage: M.<a> = LazyLaurentSeriesRing(QQ) sage: phi = sum(qpoch[i](q=a)*a^i for i in range(10)) sage: phi[:20] == M.euler()[:20] True
>>> from sage.all import * >>> M = LazyLaurentSeriesRing(QQ, names=('a',)); (a,) = M._first_ngens(1) >>> phi = sum(qpoch[i](q=a)*a**i for i in range(Integer(10))) >>> phi[:Integer(20)] == M.euler()[:Integer(20)] True
M.<a> = LazyLaurentSeriesRing(QQ) phi = sum(qpoch[i](q=a)*a^i for i in range(10)) phi[:20] == M.euler()[:20]
REFERENCES:
- residue_field()[source]¶
Return the residue field of the ring of integers of
self
.EXAMPLES:
sage: L = LazyLaurentSeriesRing(QQ, 'z') sage: L.residue_field() Rational Field
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, 'z') >>> L.residue_field() Rational Field
L = LazyLaurentSeriesRing(QQ, 'z') L.residue_field()
- series(coefficient, valuation, degree=None, constant=None)[source]¶
Return a lazy Laurent series.
INPUT:
coefficient
– Python function that computes coefficients or a listvaluation
– integer; approximate valuation of the seriesdegree
– (optional) integerconstant
– (optional) an element of the base ring
Let the coefficient of index \(i\) mean the coefficient of the term of the series with exponent \(i\).
Python function
coefficient
returns the value of the coefficient of index \(i\) from input \(s\) and \(i\) where \(s\) is the series itself.Let
valuation
be \(n\). All coefficients of index below \(n\) are zero. Ifconstant
is not specified, then thecoefficient
function is responsible to compute the values of all coefficients of index \(\ge n\). Ifdegree
orconstant
is a pair \((c,m)\), then thecoefficient
function is responsible to compute the values of all coefficients of index \(\ge n\) and \(< m\) and all the coefficients of index \(\ge m\) is the constant \(c\).EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.series(lambda s, i: i, 5, (1,10)) 5*z^5 + 6*z^6 + 7*z^7 + 8*z^8 + 9*z^9 + z^10 + z^11 + z^12 + O(z^13) sage: def g(s, i): ....: if i < 0: ....: return 1 ....: else: ....: return s.coefficient(i - 1) + i sage: e = L.series(g, -5); e z^-5 + z^-4 + z^-3 + z^-2 + z^-1 + 1 + 2*z + O(z^2) sage: f = e^-1; f z^5 - z^6 - z^11 + O(z^12) sage: f.coefficient(10) 0 sage: f.coefficient(20) 9 sage: f.coefficient(30) -219
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.series(lambda s, i: i, Integer(5), (Integer(1),Integer(10))) 5*z^5 + 6*z^6 + 7*z^7 + 8*z^8 + 9*z^9 + z^10 + z^11 + z^12 + O(z^13) >>> def g(s, i): ... if i < Integer(0): ... return Integer(1) ... else: ... return s.coefficient(i - Integer(1)) + i >>> e = L.series(g, -Integer(5)); e z^-5 + z^-4 + z^-3 + z^-2 + z^-1 + 1 + 2*z + O(z^2) >>> f = e**-Integer(1); f z^5 - z^6 - z^11 + O(z^12) >>> f.coefficient(Integer(10)) 0 >>> f.coefficient(Integer(20)) 9 >>> f.coefficient(Integer(30)) -219
L = LazyLaurentSeriesRing(ZZ, 'z') L.series(lambda s, i: i, 5, (1,10)) def g(s, i): if i < 0: return 1 else: return s.coefficient(i - 1) + i e = L.series(g, -5); e f = e^-1; f f.coefficient(10) f.coefficient(20) f.coefficient(30)
Alternatively, the
coefficient
can be a list of elements of the base ring. Then these elements are read as coefficients of the terms of degrees starting from thevaluation
. In this case,constant
may be just an element of the base ring instead of a tuple or can be simply omitted if it is zero.sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: f = L.series([1,2,3,4], -5); f z^-5 + 2*z^-4 + 3*z^-3 + 4*z^-2 sage: g = L.series([1,3,5,7,9], 5, constant=-1); g z^5 + 3*z^6 + 5*z^7 + 7*z^8 + 9*z^9 - z^10 - z^11 - z^12 + O(z^13)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> f = L.series([Integer(1),Integer(2),Integer(3),Integer(4)], -Integer(5)); f z^-5 + 2*z^-4 + 3*z^-3 + 4*z^-2 >>> g = L.series([Integer(1),Integer(3),Integer(5),Integer(7),Integer(9)], Integer(5), constant=-Integer(1)); g z^5 + 3*z^6 + 5*z^7 + 7*z^8 + 9*z^9 - z^10 - z^11 - z^12 + O(z^13)
L = LazyLaurentSeriesRing(ZZ, 'z') f = L.series([1,2,3,4], -5); f g = L.series([1,3,5,7,9], 5, constant=-1); g
- some_elements()[source]¶
Return a list of elements of
self
.EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.some_elements()[:7] [0, 1, z, -3*z^-4 + z^-3 - 12*z^-2 - 2*z^-1 - 10 - 8*z + z^2 + z^3, z^-2 + z^3 + z^4 + z^5 + O(z^6), -2*z^-3 - 2*z^-2 + 4*z^-1 + 11 - z - 34*z^2 - 31*z^3 + O(z^4), 4*z^-2 + z^-1 + z + 4*z^2 + 9*z^3 + 16*z^4 + O(z^5)] sage: L = LazyLaurentSeriesRing(GF(2), 'z') sage: L.some_elements()[:7] [0, 1, z, z^-4 + z^-3 + z^2 + z^3, z^-2, 1 + z + z^3 + z^4 + z^6 + O(z^7), z^-1 + z + z^3 + O(z^5)] sage: L = LazyLaurentSeriesRing(GF(3), 'z') sage: L.some_elements()[:7] [0, 1, z, z^-3 + z^-1 + 2 + z + z^2 + z^3, z^-2, z^-3 + z^-2 + z^-1 + 2 + 2*z + 2*z^2 + O(z^3), z^-2 + z^-1 + z + z^2 + z^4 + O(z^5)]
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.some_elements()[:Integer(7)] [0, 1, z, -3*z^-4 + z^-3 - 12*z^-2 - 2*z^-1 - 10 - 8*z + z^2 + z^3, z^-2 + z^3 + z^4 + z^5 + O(z^6), -2*z^-3 - 2*z^-2 + 4*z^-1 + 11 - z - 34*z^2 - 31*z^3 + O(z^4), 4*z^-2 + z^-1 + z + 4*z^2 + 9*z^3 + 16*z^4 + O(z^5)] >>> L = LazyLaurentSeriesRing(GF(Integer(2)), 'z') >>> L.some_elements()[:Integer(7)] [0, 1, z, z^-4 + z^-3 + z^2 + z^3, z^-2, 1 + z + z^3 + z^4 + z^6 + O(z^7), z^-1 + z + z^3 + O(z^5)] >>> L = LazyLaurentSeriesRing(GF(Integer(3)), 'z') >>> L.some_elements()[:Integer(7)] [0, 1, z, z^-3 + z^-1 + 2 + z + z^2 + z^3, z^-2, z^-3 + z^-2 + z^-1 + 2 + 2*z + 2*z^2 + O(z^3), z^-2 + z^-1 + z + z^2 + z^4 + O(z^5)]
L = LazyLaurentSeriesRing(ZZ, 'z') L.some_elements()[:7] L = LazyLaurentSeriesRing(GF(2), 'z') L.some_elements()[:7] L = LazyLaurentSeriesRing(GF(3), 'z') L.some_elements()[:7]
- taylor(f)[source]¶
Return the Taylor expansion around \(0\) of the function
f
.INPUT:
f
– a function such that one of the following works:the substitution \(f(z)\), where \(z\) is a generator of
self
\(f\) is a function of a single variable with no poles at \(0\) and has a
derivative
method
EXAMPLES:
sage: L.<z> = LazyLaurentSeriesRing(QQ) sage: x = SR.var('x') sage: f(x) = (1 + x) / (1 - x^2) sage: L.taylor(f) 1 + z + z^2 + z^3 + z^4 + z^5 + z^6 + O(z^7)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> x = SR.var('x') >>> __tmp__=var("x"); f = symbolic_expression((Integer(1) + x) / (Integer(1) - x**Integer(2))).function(x) >>> L.taylor(f) 1 + z + z^2 + z^3 + z^4 + z^5 + z^6 + O(z^7)
L.<z> = LazyLaurentSeriesRing(QQ) x = SR.var('x') f(x) = (1 + x) / (1 - x^2) L.taylor(f)
For inputs as symbolic functions/expressions, the function must not have any poles at \(0\):
sage: f(x) = (1 + x^2) / sin(x^2) sage: L.taylor(f) <repr(...) failed: ValueError: power::eval(): division by zero> sage: def g(a): return (1 + a^2) / sin(a^2) sage: L.taylor(g) z^-2 + 1 + 1/6*z^2 + 1/6*z^4 + O(z^5)
>>> from sage.all import * >>> __tmp__=var("x"); f = symbolic_expression((Integer(1) + x**Integer(2)) / sin(x**Integer(2))).function(x) >>> L.taylor(f) <repr(...) failed: ValueError: power::eval(): division by zero> >>> def g(a): return (Integer(1) + a**Integer(2)) / sin(a**Integer(2)) >>> L.taylor(g) z^-2 + 1 + 1/6*z^2 + 1/6*z^4 + O(z^5)
f(x) = (1 + x^2) / sin(x^2) L.taylor(f) def g(a): return (1 + a^2) / sin(a^2) L.taylor(g)
- class sage.rings.lazy_series_ring.LazyPowerSeriesRing(base_ring, names, sparse=True, category=None)[source]¶
Bases:
LazySeriesRing
The ring of (possibly multivariate) lazy Taylor series.
INPUT:
base_ring
– base ring of this Taylor series ringnames
– name(s) of the generator of this Taylor series ringsparse
– boolean (default:True
); whether this series is sparse or not
EXAMPLES:
sage: LazyPowerSeriesRing(ZZ, 't') Lazy Taylor Series Ring in t over Integer Ring sage: L.<x, y> = LazyPowerSeriesRing(QQ); L Multivariate Lazy Taylor Series Ring in x, y over Rational Field
>>> from sage.all import * >>> LazyPowerSeriesRing(ZZ, 't') Lazy Taylor Series Ring in t over Integer Ring >>> L = LazyPowerSeriesRing(QQ, names=('x', 'y',)); (x, y,) = L._first_ngens(2); L Multivariate Lazy Taylor Series Ring in x, y over Rational Field
LazyPowerSeriesRing(ZZ, 't') L.<x, y> = LazyPowerSeriesRing(QQ); L
- Element[source]¶
alias of
LazyPowerSeries
- fraction_field()[source]¶
Return the fraction field of
self
.If this is with a single variable over a field, then the fraction field is the field of (lazy) formal Laurent series.
Todo
Implement other fraction fields.
EXAMPLES:
sage: L.<x> = LazyPowerSeriesRing(QQ) sage: L.fraction_field() Lazy Laurent Series Ring in x over Rational Field
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('x',)); (x,) = L._first_ngens(1) >>> L.fraction_field() Lazy Laurent Series Ring in x over Rational Field
L.<x> = LazyPowerSeriesRing(QQ) L.fraction_field()
- gen(n=0)[source]¶
Return the
n
-th generator ofself
.EXAMPLES:
sage: L = LazyPowerSeriesRing(ZZ, 'z') sage: L.gen() z sage: L.gen(3) Traceback (most recent call last): ... IndexError: there is only one generator
>>> from sage.all import * >>> L = LazyPowerSeriesRing(ZZ, 'z') >>> L.gen() z >>> L.gen(Integer(3)) Traceback (most recent call last): ... IndexError: there is only one generator
L = LazyPowerSeriesRing(ZZ, 'z') L.gen() L.gen(3)
- gens()[source]¶
Return the generators of
self
.EXAMPLES:
sage: L = LazyPowerSeriesRing(ZZ, 'x,y') sage: L.gens() (x, y)
>>> from sage.all import * >>> L = LazyPowerSeriesRing(ZZ, 'x,y') >>> L.gens() (x, y)
L = LazyPowerSeriesRing(ZZ, 'x,y') L.gens()
- ngens()[source]¶
Return the number of generators of
self
.EXAMPLES:
sage: L.<z> = LazyPowerSeriesRing(ZZ) sage: L.ngens() 1
>>> from sage.all import * >>> L = LazyPowerSeriesRing(ZZ, names=('z',)); (z,) = L._first_ngens(1) >>> L.ngens() 1
L.<z> = LazyPowerSeriesRing(ZZ) L.ngens()
- residue_field()[source]¶
Return the residue field of the ring of integers of
self
.EXAMPLES:
sage: L = LazyPowerSeriesRing(QQ, 'x') sage: L.residue_field() Rational Field
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, 'x') >>> L.residue_field() Rational Field
L = LazyPowerSeriesRing(QQ, 'x') L.residue_field()
- some_elements()[source]¶
Return a list of elements of
self
.EXAMPLES:
sage: L = LazyPowerSeriesRing(ZZ, 'z') sage: L.some_elements()[:6] [0, 1, z + z^2 + z^3 + O(z^4), -12 - 8*z + z^2 + z^3, 1 + z - 2*z^2 - 7*z^3 - z^4 + 20*z^5 + 23*z^6 + O(z^7), z + 4*z^2 + 9*z^3 + 16*z^4 + 25*z^5 + 36*z^6 + O(z^7)] sage: L = LazyPowerSeriesRing(GF(3)["q"], 'z') sage: L.some_elements()[:6] [0, 1, z + q*z^2 + q*z^3 + q*z^4 + O(z^5), z + z^2 + z^3, 1 + z + z^2 + 2*z^3 + 2*z^4 + 2*z^5 + O(z^6), z + z^2 + z^4 + z^5 + O(z^7)] sage: L = LazyPowerSeriesRing(GF(3), 'q, t') sage: L.some_elements()[:6] [0, 1, q, q + q^2 + q^3, 1 + q + q^2 + (-q^3) + (-q^4) + (-q^5) + (-q^6) + O(q,t)^7, 1 + (q+t) + (q^2-q*t+t^2) + (q^3+t^3) + (q^4+q^3*t+q*t^3+t^4) + (q^5-q^4*t+q^3*t^2+q^2*t^3-q*t^4+t^5) + (q^6-q^3*t^3+t^6) + O(q,t)^7]
>>> from sage.all import * >>> L = LazyPowerSeriesRing(ZZ, 'z') >>> L.some_elements()[:Integer(6)] [0, 1, z + z^2 + z^3 + O(z^4), -12 - 8*z + z^2 + z^3, 1 + z - 2*z^2 - 7*z^3 - z^4 + 20*z^5 + 23*z^6 + O(z^7), z + 4*z^2 + 9*z^3 + 16*z^4 + 25*z^5 + 36*z^6 + O(z^7)] >>> L = LazyPowerSeriesRing(GF(Integer(3))["q"], 'z') >>> L.some_elements()[:Integer(6)] [0, 1, z + q*z^2 + q*z^3 + q*z^4 + O(z^5), z + z^2 + z^3, 1 + z + z^2 + 2*z^3 + 2*z^4 + 2*z^5 + O(z^6), z + z^2 + z^4 + z^5 + O(z^7)] >>> L = LazyPowerSeriesRing(GF(Integer(3)), 'q, t') >>> L.some_elements()[:Integer(6)] [0, 1, q, q + q^2 + q^3, 1 + q + q^2 + (-q^3) + (-q^4) + (-q^5) + (-q^6) + O(q,t)^7, 1 + (q+t) + (q^2-q*t+t^2) + (q^3+t^3) + (q^4+q^3*t+q*t^3+t^4) + (q^5-q^4*t+q^3*t^2+q^2*t^3-q*t^4+t^5) + (q^6-q^3*t^3+t^6) + O(q,t)^7]
L = LazyPowerSeriesRing(ZZ, 'z') L.some_elements()[:6] L = LazyPowerSeriesRing(GF(3)["q"], 'z') L.some_elements()[:6] L = LazyPowerSeriesRing(GF(3), 'q, t') L.some_elements()[:6]
- taylor(f)[source]¶
Return the Taylor expansion around \(0\) of the function
f
.INPUT:
f
– a function such that one of the following works:the substitution \(f(z_1, \ldots, z_n)\), where \((z_1, \ldots, z_n)\) are the generators of
self
\(f\) is a function with no poles at \(0\) and has a
derivative
method
Warning
For inputs as symbolic functions/expressions, this does not check that the function does not have poles at \(0\).
EXAMPLES:
sage: L.<z> = LazyPowerSeriesRing(QQ) sage: x = SR.var('x') sage: f(x) = (1 + x) / (1 - x^3) sage: L.taylor(f) 1 + z + z^3 + z^4 + z^6 + O(z^7) sage: (1 + z) / (1 - z^3) 1 + z + z^3 + z^4 + z^6 + O(z^7) sage: f(x) = cos(x + pi/2) sage: L.taylor(f) -z + 1/6*z^3 - 1/120*z^5 + O(z^7)
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> x = SR.var('x') >>> __tmp__=var("x"); f = symbolic_expression((Integer(1) + x) / (Integer(1) - x**Integer(3))).function(x) >>> L.taylor(f) 1 + z + z^3 + z^4 + z^6 + O(z^7) >>> (Integer(1) + z) / (Integer(1) - z**Integer(3)) 1 + z + z^3 + z^4 + z^6 + O(z^7) >>> __tmp__=var("x"); f = symbolic_expression(cos(x + pi/Integer(2))).function(x) >>> L.taylor(f) -z + 1/6*z^3 - 1/120*z^5 + O(z^7)
L.<z> = LazyPowerSeriesRing(QQ) x = SR.var('x') f(x) = (1 + x) / (1 - x^3) L.taylor(f) (1 + z) / (1 - z^3) f(x) = cos(x + pi/2) L.taylor(f)
For inputs as symbolic functions/expressions, the function must not have any poles at \(0\):
sage: L.<z> = LazyPowerSeriesRing(QQ, sparse=True) sage: f = 1 / sin(x) sage: L.taylor(f) <repr(...) failed: ValueError: power::eval(): division by zero>
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, sparse=True, names=('z',)); (z,) = L._first_ngens(1) >>> f = Integer(1) / sin(x) >>> L.taylor(f) <repr(...) failed: ValueError: power::eval(): division by zero>
L.<z> = LazyPowerSeriesRing(QQ, sparse=True) f = 1 / sin(x) L.taylor(f)
Different multivariate inputs:
sage: L.<a,b> = LazyPowerSeriesRing(QQ) sage: def f(x, y): return (1 + x) / (1 + y) sage: L.taylor(f) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7 sage: g(w, z) = (1 + w) / (1 + z) sage: L.taylor(g) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7 sage: y = SR.var('y') sage: h = (1 + x) / (1 + y) sage: L.taylor(h) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('a', 'b',)); (a, b,) = L._first_ngens(2) >>> def f(x, y): return (Integer(1) + x) / (Integer(1) + y) >>> L.taylor(f) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7 >>> __tmp__=var("w,z"); g = symbolic_expression((Integer(1) + w) / (Integer(1) + z)).function(w,z) >>> L.taylor(g) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7 >>> y = SR.var('y') >>> h = (Integer(1) + x) / (Integer(1) + y) >>> L.taylor(h) 1 + (a-b) + (-a*b+b^2) + (a*b^2-b^3) + (-a*b^3+b^4) + (a*b^4-b^5) + (-a*b^5+b^6) + O(a,b)^7
L.<a,b> = LazyPowerSeriesRing(QQ) def f(x, y): return (1 + x) / (1 + y) L.taylor(f) g(w, z) = (1 + w) / (1 + z) L.taylor(g) y = SR.var('y') h = (1 + x) / (1 + y) L.taylor(h)
- class sage.rings.lazy_series_ring.LazySeriesRing[source]¶
Bases:
UniqueRepresentation
,Parent
Abstract base class for lazy series.
- characteristic()[source]¶
Return the characteristic of this lazy power series ring, which is the same as the characteristic of its base ring.
EXAMPLES:
sage: L.<t> = LazyLaurentSeriesRing(ZZ) sage: L.characteristic() 0 sage: R.<w> = LazyLaurentSeriesRing(GF(11)); R Lazy Laurent Series Ring in w over Finite Field of size 11 sage: R.characteristic() 11 sage: R.<x, y> = LazyPowerSeriesRing(GF(7)); R Multivariate Lazy Taylor Series Ring in x, y over Finite Field of size 7 sage: R.characteristic() 7 sage: L = LazyDirichletSeriesRing(ZZ, "s") sage: L.characteristic() 0
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, names=('t',)); (t,) = L._first_ngens(1) >>> L.characteristic() 0 >>> R = LazyLaurentSeriesRing(GF(Integer(11)), names=('w',)); (w,) = R._first_ngens(1); R Lazy Laurent Series Ring in w over Finite Field of size 11 >>> R.characteristic() 11 >>> R = LazyPowerSeriesRing(GF(Integer(7)), names=('x', 'y',)); (x, y,) = R._first_ngens(2); R Multivariate Lazy Taylor Series Ring in x, y over Finite Field of size 7 >>> R.characteristic() 7 >>> L = LazyDirichletSeriesRing(ZZ, "s") >>> L.characteristic() 0
L.<t> = LazyLaurentSeriesRing(ZZ) L.characteristic() R.<w> = LazyLaurentSeriesRing(GF(11)); R R.characteristic() R.<x, y> = LazyPowerSeriesRing(GF(7)); R R.characteristic() L = LazyDirichletSeriesRing(ZZ, "s") L.characteristic()
- is_exact()[source]¶
Return if
self
is exact or not.EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.is_exact() True sage: L = LazyLaurentSeriesRing(RR, 'z') sage: L.is_exact() False
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.is_exact() True >>> L = LazyLaurentSeriesRing(RR, 'z') >>> L.is_exact() False
L = LazyLaurentSeriesRing(ZZ, 'z') L.is_exact() L = LazyLaurentSeriesRing(RR, 'z') L.is_exact()
- is_sparse()[source]¶
Return whether
self
is sparse or not.EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z', sparse=False) sage: L.is_sparse() False sage: L = LazyLaurentSeriesRing(ZZ, 'z', sparse=True) sage: L.is_sparse() True
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z', sparse=False) >>> L.is_sparse() False >>> L = LazyLaurentSeriesRing(ZZ, 'z', sparse=True) >>> L.is_sparse() True
L = LazyLaurentSeriesRing(ZZ, 'z', sparse=False) L.is_sparse() L = LazyLaurentSeriesRing(ZZ, 'z', sparse=True) L.is_sparse()
- one()[source]¶
Return the constant series \(1\).
EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.one() 1 sage: L = LazyPowerSeriesRing(ZZ, 'z') sage: L.one() 1 sage: m = SymmetricFunctions(ZZ).m() # needs sage.modules sage: L = LazySymmetricFunctions(m) # needs sage.modules sage: L.one() # needs sage.modules m[]
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.one() 1 >>> L = LazyPowerSeriesRing(ZZ, 'z') >>> L.one() 1 >>> m = SymmetricFunctions(ZZ).m() # needs sage.modules >>> L = LazySymmetricFunctions(m) # needs sage.modules >>> L.one() # needs sage.modules m[]
L = LazyLaurentSeriesRing(ZZ, 'z') L.one() L = LazyPowerSeriesRing(ZZ, 'z') L.one() m = SymmetricFunctions(ZZ).m() # needs sage.modules L = LazySymmetricFunctions(m) # needs sage.modules L.one() # needs sage.modules
- options = Current options for lazy series rings - constant_length: 3 - display_length: 7 - halting_precision: None - secure: False[source]¶
- prod(f, a=None, b=+Infinity, add_one=False)[source]¶
The product of elements of
self
.INPUT:
f
– list (or iterable) of elements ofself
a
,b
– optional argumentsadd_one
– (default:False
) ifTrue
, then converts a lazy series \(p_i\) fromargs
into \(1 + p_i\) for the product
If
a
andb
are both integers, then this returns the product \(\prod_{i=a}^b f(i)\), where \(f(i) = p_i\) ifadd_one=False
or \(f(i) = 1 + p_i\) otherwise. Ifb
is not specified, then we consider \(b = \infty\). Note this corresponds to the Pythonrange(a, b+1)
.If \(a\) is any other iterable, then this returns the product \(\prod_{i \in a} f(i)\), where \(f(i) = p_i\) if
add_one=False
or \(f(i) = 1 + p_i\).Note
For infinite products, it is faster to use
add_one=True
since the implementation is based on \(p_i\) in \(\prod_i (1 + p_i)\).Warning
When
f
is an infinite generator, then the first argumenta
must beTrue
. Otherwise this will loop forever.Warning
For an infinite product of the form \(\prod_i (1 + p_i)\), if \(p_i = 0\), then this will loop forever.
EXAMPLES:
sage: L.<t> = LazyLaurentSeriesRing(QQ) sage: euler = L.prod(lambda n: 1 - t^n, PositiveIntegers()) sage: euler 1 - t - t^2 + t^5 + O(t^7) sage: 1 / euler 1 + t + 2*t^2 + 3*t^3 + 5*t^4 + 7*t^5 + 11*t^6 + O(t^7) sage: euler - L.euler() O(t^7) sage: L.prod(lambda n: -t^n, 1, add_one=True) 1 - t - t^2 + t^5 + O(t^7) sage: L.prod((1 - t^n for n in PositiveIntegers()), True) 1 - t - t^2 + t^5 + O(t^7) sage: L.prod((-t^n for n in PositiveIntegers()), True, add_one=True) 1 - t - t^2 + t^5 + O(t^7) sage: L.prod((1 + t^(n-3) for n in PositiveIntegers()), True) 2*t^-3 + 4*t^-2 + 4*t^-1 + 4 + 6*t + 10*t^2 + 16*t^3 + O(t^4) sage: L.prod(lambda n: 2 + t^n, -3, 5) 96*t^-6 + 240*t^-5 + 336*t^-4 + 840*t^-3 + 984*t^-2 + 1248*t^-1 + 1980 + 1668*t + 1824*t^2 + 1872*t^3 + 1782*t^4 + 1710*t^5 + 1314*t^6 + 1122*t^7 + 858*t^8 + 711*t^9 + 438*t^10 + 282*t^11 + 210*t^12 + 84*t^13 + 60*t^14 + 24*t^15 sage: L.prod(lambda n: t^n / (1 + abs(n)), -2, 2, add_one=True) 1/3*t^-3 + 5/6*t^-2 + 13/9*t^-1 + 25/9 + 13/9*t + 5/6*t^2 + 1/3*t^3 sage: L.prod(lambda n: t^-2 + t^n / n, -4, -2) 1/24*t^-9 - 1/8*t^-8 - 1/6*t^-7 + 1/2*t^-6 sage: D = LazyDirichletSeriesRing(QQ, "s") sage: D.prod(lambda p: (1+D(1, valuation=p)).inverse(), Primes()) 1 - 1/(2^s) - 1/(3^s) + 1/(4^s) - 1/(5^s) + 1/(6^s) - 1/(7^s) + O(1/(8^s)) sage: D.prod(lambda p: D(1, valuation=p), Primes(), add_one=True) 1 + 1/(2^s) + 1/(3^s) + 1/(5^s) + 1/(6^s) + 1/(7^s) + O(1/(8^s))
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('t',)); (t,) = L._first_ngens(1) >>> euler = L.prod(lambda n: Integer(1) - t**n, PositiveIntegers()) >>> euler 1 - t - t^2 + t^5 + O(t^7) >>> Integer(1) / euler 1 + t + 2*t^2 + 3*t^3 + 5*t^4 + 7*t^5 + 11*t^6 + O(t^7) >>> euler - L.euler() O(t^7) >>> L.prod(lambda n: -t**n, Integer(1), add_one=True) 1 - t - t^2 + t^5 + O(t^7) >>> L.prod((Integer(1) - t**n for n in PositiveIntegers()), True) 1 - t - t^2 + t^5 + O(t^7) >>> L.prod((-t**n for n in PositiveIntegers()), True, add_one=True) 1 - t - t^2 + t^5 + O(t^7) >>> L.prod((Integer(1) + t**(n-Integer(3)) for n in PositiveIntegers()), True) 2*t^-3 + 4*t^-2 + 4*t^-1 + 4 + 6*t + 10*t^2 + 16*t^3 + O(t^4) >>> L.prod(lambda n: Integer(2) + t**n, -Integer(3), Integer(5)) 96*t^-6 + 240*t^-5 + 336*t^-4 + 840*t^-3 + 984*t^-2 + 1248*t^-1 + 1980 + 1668*t + 1824*t^2 + 1872*t^3 + 1782*t^4 + 1710*t^5 + 1314*t^6 + 1122*t^7 + 858*t^8 + 711*t^9 + 438*t^10 + 282*t^11 + 210*t^12 + 84*t^13 + 60*t^14 + 24*t^15 >>> L.prod(lambda n: t**n / (Integer(1) + abs(n)), -Integer(2), Integer(2), add_one=True) 1/3*t^-3 + 5/6*t^-2 + 13/9*t^-1 + 25/9 + 13/9*t + 5/6*t^2 + 1/3*t^3 >>> L.prod(lambda n: t**-Integer(2) + t**n / n, -Integer(4), -Integer(2)) 1/24*t^-9 - 1/8*t^-8 - 1/6*t^-7 + 1/2*t^-6 >>> D = LazyDirichletSeriesRing(QQ, "s") >>> D.prod(lambda p: (Integer(1)+D(Integer(1), valuation=p)).inverse(), Primes()) 1 - 1/(2^s) - 1/(3^s) + 1/(4^s) - 1/(5^s) + 1/(6^s) - 1/(7^s) + O(1/(8^s)) >>> D.prod(lambda p: D(Integer(1), valuation=p), Primes(), add_one=True) 1 + 1/(2^s) + 1/(3^s) + 1/(5^s) + 1/(6^s) + 1/(7^s) + O(1/(8^s))
L.<t> = LazyLaurentSeriesRing(QQ) euler = L.prod(lambda n: 1 - t^n, PositiveIntegers()) euler 1 / euler euler - L.euler() L.prod(lambda n: -t^n, 1, add_one=True) L.prod((1 - t^n for n in PositiveIntegers()), True) L.prod((-t^n for n in PositiveIntegers()), True, add_one=True) L.prod((1 + t^(n-3) for n in PositiveIntegers()), True) L.prod(lambda n: 2 + t^n, -3, 5) L.prod(lambda n: t^n / (1 + abs(n)), -2, 2, add_one=True) L.prod(lambda n: t^-2 + t^n / n, -4, -2) D = LazyDirichletSeriesRing(QQ, "s") D.prod(lambda p: (1+D(1, valuation=p)).inverse(), Primes()) D.prod(lambda p: D(1, valuation=p), Primes(), add_one=True)
- sum(f, a=None, b=+Infinity)[source]¶
The sum of elements of
self
.INPUT:
f
– list (or iterable or function) of elements ofself
a
,b
– optional arguments
If
a
andb
are both integers, then this returns the sum \(\sum_{i=a}^b f(i)\). Ifb
is not specified, then we consider \(b = \infty\). Note this corresponds to the Pythonrange(a, b+1)
.If \(a\) is any other iterable, then this returns the sum \(\sum{i \in a} f(i)\).
Warning
When
f
is an infinite generator, then the first argumenta
must beTrue
. Otherwise this will loop forever.Warning
For an infinite sum of the form \(\sum_i s_i\), if \(s_i = 0\), then this will loop forever.
EXAMPLES:
sage: L.<t> = LazyLaurentSeriesRing(QQ) sage: L.sum(lambda n: t^n / (n+1), PositiveIntegers()) 1/2*t + 1/3*t^2 + 1/4*t^3 + 1/5*t^4 + 1/6*t^5 + 1/7*t^6 + 1/8*t^7 + O(t^8) sage: L.<z> = LazyPowerSeriesRing(QQ) sage: T = L.undefined(1) sage: D = L.undefined(0) sage: H = L.sum(lambda k: T(z^k)/k, 2) sage: T.define(z*exp(T)*D) sage: D.define(exp(H)) sage: T z + z^2 + 2*z^3 + 4*z^4 + 9*z^5 + 20*z^6 + 48*z^7 + O(z^8) sage: D 1 + 1/2*z^2 + 1/3*z^3 + 7/8*z^4 + 11/30*z^5 + 281/144*z^6 + O(z^7)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('t',)); (t,) = L._first_ngens(1) >>> L.sum(lambda n: t**n / (n+Integer(1)), PositiveIntegers()) 1/2*t + 1/3*t^2 + 1/4*t^3 + 1/5*t^4 + 1/6*t^5 + 1/7*t^6 + 1/8*t^7 + O(t^8) >>> L = LazyPowerSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> T = L.undefined(Integer(1)) >>> D = L.undefined(Integer(0)) >>> H = L.sum(lambda k: T(z**k)/k, Integer(2)) >>> T.define(z*exp(T)*D) >>> D.define(exp(H)) >>> T z + z^2 + 2*z^3 + 4*z^4 + 9*z^5 + 20*z^6 + 48*z^7 + O(z^8) >>> D 1 + 1/2*z^2 + 1/3*z^3 + 7/8*z^4 + 11/30*z^5 + 281/144*z^6 + O(z^7)
L.<t> = LazyLaurentSeriesRing(QQ) L.sum(lambda n: t^n / (n+1), PositiveIntegers()) L.<z> = LazyPowerSeriesRing(QQ) T = L.undefined(1) D = L.undefined(0) H = L.sum(lambda k: T(z^k)/k, 2) T.define(z*exp(T)*D) D.define(exp(H)) T D
We verify the Rogers-Ramanujan identities up to degree 100:
sage: L.<q> = LazyPowerSeriesRing(QQ) sage: Gpi = L.prod(lambda k: -q^(1+5*k), 0, oo, add_one=True) sage: Gpi *= L.prod(lambda k: -q^(4+5*k), 0, oo, add_one=True) sage: Gp = 1 / Gpi sage: G = L.sum(lambda n: q^(n^2) / prod(1 - q^(k+1) for k in range(n)), 0, oo) sage: G - Gp O(q^7) sage: all(G[k] == Gp[k] for k in range(100)) True sage: Hpi = L.prod(lambda k: -q^(2+5*k), 0, oo, add_one=True) sage: Hpi *= L.prod(lambda k: -q^(3+5*k), 0, oo, add_one=True) sage: Hp = 1 / Hpi sage: H = L.sum(lambda n: q^(n^2+n) / prod(1 - q^(k+1) for k in range(n)), 0, oo) sage: H - Hp O(q^7) sage: all(H[k] == Hp[k] for k in range(100)) True
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('q',)); (q,) = L._first_ngens(1) >>> Gpi = L.prod(lambda k: -q**(Integer(1)+Integer(5)*k), Integer(0), oo, add_one=True) >>> Gpi *= L.prod(lambda k: -q**(Integer(4)+Integer(5)*k), Integer(0), oo, add_one=True) >>> Gp = Integer(1) / Gpi >>> G = L.sum(lambda n: q**(n**Integer(2)) / prod(Integer(1) - q**(k+Integer(1)) for k in range(n)), Integer(0), oo) >>> G - Gp O(q^7) >>> all(G[k] == Gp[k] for k in range(Integer(100))) True >>> Hpi = L.prod(lambda k: -q**(Integer(2)+Integer(5)*k), Integer(0), oo, add_one=True) >>> Hpi *= L.prod(lambda k: -q**(Integer(3)+Integer(5)*k), Integer(0), oo, add_one=True) >>> Hp = Integer(1) / Hpi >>> H = L.sum(lambda n: q**(n**Integer(2)+n) / prod(Integer(1) - q**(k+Integer(1)) for k in range(n)), Integer(0), oo) >>> H - Hp O(q^7) >>> all(H[k] == Hp[k] for k in range(Integer(100))) True
L.<q> = LazyPowerSeriesRing(QQ) Gpi = L.prod(lambda k: -q^(1+5*k), 0, oo, add_one=True) Gpi *= L.prod(lambda k: -q^(4+5*k), 0, oo, add_one=True) Gp = 1 / Gpi G = L.sum(lambda n: q^(n^2) / prod(1 - q^(k+1) for k in range(n)), 0, oo) G - Gp all(G[k] == Gp[k] for k in range(100)) Hpi = L.prod(lambda k: -q^(2+5*k), 0, oo, add_one=True) Hpi *= L.prod(lambda k: -q^(3+5*k), 0, oo, add_one=True) Hp = 1 / Hpi H = L.sum(lambda n: q^(n^2+n) / prod(1 - q^(k+1) for k in range(n)), 0, oo) H - Hp all(H[k] == Hp[k] for k in range(100))
sage: D = LazyDirichletSeriesRing(QQ, "s") sage: D.sum(lambda p: D(1, valuation=p), Primes()) 1/(2^s) + 1/(3^s) + 1/(5^s) + 1/(7^s) + O(1/(9^s))
>>> from sage.all import * >>> D = LazyDirichletSeriesRing(QQ, "s") >>> D.sum(lambda p: D(Integer(1), valuation=p), Primes()) 1/(2^s) + 1/(3^s) + 1/(5^s) + 1/(7^s) + O(1/(9^s))
D = LazyDirichletSeriesRing(QQ, "s") D.sum(lambda p: D(1, valuation=p), Primes())
>>> from sage.all import * >>> D = LazyDirichletSeriesRing(QQ, "s") >>> D.sum(lambda p: D(Integer(1), valuation=p), Primes()) 1/(2^s) + 1/(3^s) + 1/(5^s) + 1/(7^s) + O(1/(9^s))
D = LazyDirichletSeriesRing(QQ, "s") D.sum(lambda p: D(1, valuation=p), Primes())
- undefined(valuation=None)[source]¶
Return an uninitialized series.
INPUT:
valuation
– integer; a lower bound for the valuation of the series
Power series can be defined recursively (see
sage.rings.lazy_series.LazyModuleElement.define()
for more examples).EXAMPLES:
sage: L.<z> = LazyPowerSeriesRing(QQ) sage: s = L.undefined(1) sage: s.define(z + (s^2+s(z^2))/2) sage: s z + z^2 + z^3 + 2*z^4 + 3*z^5 + 6*z^6 + 11*z^7 + O(z^8)
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> s = L.undefined(Integer(1)) >>> s.define(z + (s**Integer(2)+s(z**Integer(2)))/Integer(2)) >>> s z + z^2 + z^3 + 2*z^4 + 3*z^5 + 6*z^6 + 11*z^7 + O(z^8)
L.<z> = LazyPowerSeriesRing(QQ) s = L.undefined(1) s.define(z + (s^2+s(z^2))/2) s
Alternatively:
sage: L.<z> = LazyLaurentSeriesRing(QQ) sage: f = L(None, valuation=-1) sage: f.define(z^-1 + z^2*f^2) sage: f z^-1 + 1 + 2*z + 5*z^2 + 14*z^3 + 42*z^4 + 132*z^5 + O(z^6)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> f = L(None, valuation=-Integer(1)) >>> f.define(z**-Integer(1) + z**Integer(2)*f**Integer(2)) >>> f z^-1 + 1 + 2*z + 5*z^2 + 14*z^3 + 42*z^4 + 132*z^5 + O(z^6)
L.<z> = LazyLaurentSeriesRing(QQ) f = L(None, valuation=-1) f.define(z^-1 + z^2*f^2) f
- unknown(valuation=None)[source]¶
Return an uninitialized series.
INPUT:
valuation
– integer; a lower bound for the valuation of the series
Power series can be defined recursively (see
sage.rings.lazy_series.LazyModuleElement.define()
for more examples).EXAMPLES:
sage: L.<z> = LazyPowerSeriesRing(QQ) sage: s = L.undefined(1) sage: s.define(z + (s^2+s(z^2))/2) sage: s z + z^2 + z^3 + 2*z^4 + 3*z^5 + 6*z^6 + 11*z^7 + O(z^8)
>>> from sage.all import * >>> L = LazyPowerSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> s = L.undefined(Integer(1)) >>> s.define(z + (s**Integer(2)+s(z**Integer(2)))/Integer(2)) >>> s z + z^2 + z^3 + 2*z^4 + 3*z^5 + 6*z^6 + 11*z^7 + O(z^8)
L.<z> = LazyPowerSeriesRing(QQ) s = L.undefined(1) s.define(z + (s^2+s(z^2))/2) s
Alternatively:
sage: L.<z> = LazyLaurentSeriesRing(QQ) sage: f = L(None, valuation=-1) sage: f.define(z^-1 + z^2*f^2) sage: f z^-1 + 1 + 2*z + 5*z^2 + 14*z^3 + 42*z^4 + 132*z^5 + O(z^6)
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(QQ, names=('z',)); (z,) = L._first_ngens(1) >>> f = L(None, valuation=-Integer(1)) >>> f.define(z**-Integer(1) + z**Integer(2)*f**Integer(2)) >>> f z^-1 + 1 + 2*z + 5*z^2 + 14*z^3 + 42*z^4 + 132*z^5 + O(z^6)
L.<z> = LazyLaurentSeriesRing(QQ) f = L(None, valuation=-1) f.define(z^-1 + z^2*f^2) f
- zero()[source]¶
Return the zero series.
EXAMPLES:
sage: L = LazyLaurentSeriesRing(ZZ, 'z') sage: L.zero() 0 sage: s = SymmetricFunctions(ZZ).s() # needs sage.modules sage: L = LazySymmetricFunctions(s) # needs sage.modules sage: L.zero() # needs sage.modules 0 sage: L = LazyDirichletSeriesRing(ZZ, 'z') sage: L.zero() 0 sage: L = LazyPowerSeriesRing(ZZ, 'z') sage: L.zero() 0
>>> from sage.all import * >>> L = LazyLaurentSeriesRing(ZZ, 'z') >>> L.zero() 0 >>> s = SymmetricFunctions(ZZ).s() # needs sage.modules >>> L = LazySymmetricFunctions(s) # needs sage.modules >>> L.zero() # needs sage.modules 0 >>> L = LazyDirichletSeriesRing(ZZ, 'z') >>> L.zero() 0 >>> L = LazyPowerSeriesRing(ZZ, 'z') >>> L.zero() 0
L = LazyLaurentSeriesRing(ZZ, 'z') L.zero() s = SymmetricFunctions(ZZ).s() # needs sage.modules L = LazySymmetricFunctions(s) # needs sage.modules L.zero() # needs sage.modules L = LazyDirichletSeriesRing(ZZ, 'z') L.zero() L = LazyPowerSeriesRing(ZZ, 'z') L.zero()
- class sage.rings.lazy_series_ring.LazySymmetricFunctions(basis, sparse=True, category=None)[source]¶
Bases:
LazyCompletionGradedAlgebra
The ring of lazy symmetric functions.
INPUT:
basis
– the ring of symmetric functionsnames
– name(s) of the alphabetssparse
– boolean (default:True
); whether we use a sparse or a dense representation
EXAMPLES:
sage: s = SymmetricFunctions(ZZ).s() # needs sage.modules sage: LazySymmetricFunctions(s) # needs sage.modules Lazy completion of Symmetric Functions over Integer Ring in the Schur basis sage: m = SymmetricFunctions(ZZ).m() # needs sage.modules sage: LazySymmetricFunctions(tensor([s, m])) # needs sage.modules Lazy completion of Symmetric Functions over Integer Ring in the Schur basis # Symmetric Functions over Integer Ring in the monomial basis
>>> from sage.all import * >>> s = SymmetricFunctions(ZZ).s() # needs sage.modules >>> LazySymmetricFunctions(s) # needs sage.modules Lazy completion of Symmetric Functions over Integer Ring in the Schur basis >>> m = SymmetricFunctions(ZZ).m() # needs sage.modules >>> LazySymmetricFunctions(tensor([s, m])) # needs sage.modules Lazy completion of Symmetric Functions over Integer Ring in the Schur basis # Symmetric Functions over Integer Ring in the monomial basis
s = SymmetricFunctions(ZZ).s() # needs sage.modules LazySymmetricFunctions(s) # needs sage.modules m = SymmetricFunctions(ZZ).m() # needs sage.modules LazySymmetricFunctions(tensor([s, m])) # needs sage.modules
- Element[source]¶
alias of
LazySymmetricFunction