2014-09-01 18:56 UTC+01:00, Vincent Delecroix <20100.delecr...@gmail.com>:
> 2014-09-01 14:13 UTC+01:00, slelievre :
>> Daniel Krenn wrote:
>>
>>> I want to solve polynomial equations and in order
>>> to do so, I do something like:
>>> sage: R. = PolynomialRing(QQ, order='lex')
>>> sage: I
2014-09-01 14:13 UTC+01:00, slelievre :
> Daniel Krenn wrote:
>
>> I want to solve polynomial equations and in order
>> to do so, I do something like:
>> sage: R. = PolynomialRing(QQ, order='lex')
>> sage: I = R.ideal([x*y-1, x^2-y^2])
>> sage: I.groebner_basis()
>> [x - y^3, y^4 -
Daniel Krenn wrote:
> I want to solve polynomial equations and in order
> to do so, I do something like:
> sage: R. = PolynomialRing(QQ, order='lex')
> sage: I = R.ideal([x*y-1, x^2-y^2])
> sage: I.groebner_basis()
> [x - y^3, y^4 - 1]
and then wrote:
> Meanwhile, I found, w
2014-08-31 11:51 UTC+02:00, Daniel Krenn :
> Am 2014-08-29 um 21:25 schrieb Daniel Krenn:
>> I want to solve polynomial equations and in order to do so, I do
>> something like:
>>
>> sage: R. = PolynomialRing(QQ, order='lex')
>> sage: I = R.ideal([x*y-1, x^2-y^2])
>> sage: I.groebner_basis()
>> [x
Am 2014-08-29 um 21:25 schrieb Daniel Krenn:
> I want to solve polynomial equations and in order to do so, I do
> something like:
>
> sage: R. = PolynomialRing(QQ, order='lex')
> sage: I = R.ideal([x*y-1, x^2-y^2])
> sage: I.groebner_basis()
> [x - y^3, y^4 - 1]
Meanwhile, I found, which seems to
> ("solve" seems to be very much an overkill and it is not that
> transparent in what it does...)
Definitely! And I won't even believe the output...
> I want to solve polynomial equations and in order to do so, I do
> something like:
>
> sage: R. = PolynomialRing(QQ, order='lex')
> sage: I = R.id