Mister Exam
Other calculators
- Canonical form of a elliptical paraboloid
- Canonical form of a double hyperboloid
- Canonical form of a imaginary ellipsoid
- Canonical form of a degenerate ellipse
- Canonical form of a parabola
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How to use it?
- Canonical form:
- 4x^2-16y^2-8x+96y-204=0
- 2x1^2+2x2^2+2x3^2+2x1x2+2x1x3+2x2x3
- 9x^2-4xy+6y^2+16x-8y-2
- x^2+4y^2+9z^2-4xy+6xz-12yz-2x+4y-6z+1=0
- Plot:
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-1-(36*(x^2-y^2+5*x+6)-(36*x+132)*(2*x+5))/((x^2-y^2+5*x+6)^2+4*x^2*y+25*y^2+20*x*y^2)=0
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x^2+x*y^2=1
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x^2+(y-cbrt(x^2))^2=1
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sqrt(x)+sqrt(y)=1
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Identical expressions
- two x1^ two + two x2^2+2x3^2+2x1x2+2x1x3+2x2x3
- 2x1 squared plus 2x2 squared plus 2x3 squared plus 2x1x2 plus 2x1x3 plus 2x2x3
- two x1 to the power of two plus two x2 squared plus 2x3 squared plus 2x1x2 plus 2x1x3 plus 2x2x3
- 2x12+2x22+2x32+2x1x2+2x1x3+2x2x3
- 2x1²+2x2²+2x3²+2x1x2+2x1x3+2x2x3
- 2x1 to the power of 2+2x2 to the power of 2+2x3 to the power of 2+2x1x2+2x1x3+2x2x3
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Similar expressions
- 2x1^2+2x2^2-2x3^2+2x1x2+2x1x3+2x2x3
- 2x1^2-2x2^2+2x3^2+2x1x2+2x1x3+2x2x3
- 2x1^2+2x2^2+2x3^2+2x1x2+2x1x3-2x2x3
- 2x1^2+2x2^2+2x3^2-2x1x2+2x1x3+2x2x3
- 2x1^2+2x2^2+2x3^2+2x1x2-2x1x3+2x2x3
2x1^2+2x2^2+2x3^2+2x1x2+2x1x3+2x2x3 canonical form
The teacher will be very surprised to see your correct solution 😉
The solution
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2 2 2 2*x1 + 2*x2 + 2*x3 + 2*x1*x2 + 2*x1*x3 + 2*x2*x3 = 0
$$2 x_{1}^{2} + 2 x_{1} x_{2} + 2 x_{1} x_{3} + 2 x_{2}^{2} + 2 x_{2} x_{3} + 2 x_{3}^{2} = 0$$
2*x1^2 + 2*x1*x2 + 2*x1*x3 + 2*x2^2 + 2*x2*x3 + 2*x3^2 = 0
Invariants method
Given equation of the surface of 2-order:
$$2 x_{1}^{2} + 2 x_{1} x_{2} + 2 x_{1} x_{3} + 2 x_{2}^{2} + 2 x_{2} x_{3} + 2 x_{3}^{2} = 0$$
This equation looks like:
$$a_{11} x_{3}^{2} + 2 a_{12} x_{2} x_{3} + 2 a_{13} x_{1} x_{3} + a_{22} x_{2}^{2} + 2 a_{23} x_{1} x_{2} + a_{33} x_{1}^{2} + 2 a_{14} x_{3} + 2 a_{24} x_{2} + 2 a_{34} x_{1} + a_{44} = 0$$
where
$$a_{11} = 2$$
$$a_{12} = 1$$
$$a_{13} = 1$$
$$a_{14} = 0$$
$$a_{22} = 2$$
$$a_{23} = 1$$
$$a_{24} = 0$$
$$a_{33} = 2$$
$$a_{34} = 0$$
$$a_{44} = 0$$
The invariants of the equation when converting coordinates are determinants:
$$I_{1} = a_{11} + a_{22} + a_{33}$$
$$I_{3} = \left|\begin{matrix}a_{11} & a_{12} & a_{13}\\a_{12} & a_{22} & a_{23}\\a_{13} & a_{23} & a_{33}\end{matrix}\right|$$
$$I_{4} = \left|\begin{matrix}a_{11} & a_{12} & a_{13} & a_{14}\\a_{12} & a_{22} & a_{23} & a_{24}\\a_{13} & a_{23} & a_{33} & a_{34}\\a_{14} & a_{24} & a_{34} & a_{44}\end{matrix}\right|$$
$$I{\left(\lambda \right)} = \left|\begin{matrix}a_{11} - \lambda & a_{12} & a_{13}\\a_{12} & a_{22} - \lambda & a_{23}\\a_{13} & a_{23} & a_{33} - \lambda\end{matrix}\right|$$
substitute coefficients
$$I_{1} = 6$$
$$I_{3} = \left|\begin{matrix}2 & 1 & 1\\1 & 2 & 1\\1 & 1 & 2\end{matrix}\right|$$
$$I_{4} = \left|\begin{matrix}2 & 1 & 1 & 0\\1 & 2 & 1 & 0\\1 & 1 & 2 & 0\\0 & 0 & 0 & 0\end{matrix}\right|$$
$$I{\left(\lambda \right)} = \left|\begin{matrix}- \lambda + 2 & 1 & 1\\1 & - \lambda + 2 & 1\\1 & 1 & - \lambda + 2\end{matrix}\right|$$
$$I_{1} = 6$$
$$I_{2} = 9$$
$$I_{3} = 4$$
$$I_{4} = 0$$
$$I{\left(\lambda \right)} = - \lambda^{3} + 6 \lambda^{2} - 9 \lambda + 4$$
$$K_{2} = 0$$
$$K_{3} = 0$$
Because
then by type of surface:
you need to
Make the characteristic equation for the surface:
$$- I_{1} \lambda^{2} + \lambda^{3} + I_{2} \lambda - I_{3} = 0$$
or
$$\lambda^{3} - 6 \lambda^{2} + 9 \lambda - 4 = 0$$
Solve this equation
$$\lambda_{1} = 4$$
$$\lambda_{2} = 1$$
$$\lambda_{3} = 1$$
then the canonical form of the equation will be
$$\left(\tilde x1^{2} \lambda_{3} + \left(\tilde x2^{2} \lambda_{2} + \tilde x3^{2} \lambda_{1}\right)\right) + \frac{I_{4}}{I_{3}} = 0$$
$$\tilde x1^{2} + \tilde x2^{2} + 4 \tilde x3^{2} = 0$$
$$\frac{\tilde x1^{2}}{1^{2}} + \left(\frac{\tilde x2^{2}}{1^{2}} + \frac{\tilde x3^{2}}{\left(\frac{1}{2}\right)^{2}}\right) = 0$$
this equation is fora type imaginary cone
- reduced to canonical form
$$2 x_{1}^{2} + 2 x_{1} x_{2} + 2 x_{1} x_{3} + 2 x_{2}^{2} + 2 x_{2} x_{3} + 2 x_{3}^{2} = 0$$
This equation looks like:
$$a_{11} x_{3}^{2} + 2 a_{12} x_{2} x_{3} + 2 a_{13} x_{1} x_{3} + a_{22} x_{2}^{2} + 2 a_{23} x_{1} x_{2} + a_{33} x_{1}^{2} + 2 a_{14} x_{3} + 2 a_{24} x_{2} + 2 a_{34} x_{1} + a_{44} = 0$$
where
$$a_{11} = 2$$
$$a_{12} = 1$$
$$a_{13} = 1$$
$$a_{14} = 0$$
$$a_{22} = 2$$
$$a_{23} = 1$$
$$a_{24} = 0$$
$$a_{33} = 2$$
$$a_{34} = 0$$
$$a_{44} = 0$$
The invariants of the equation when converting coordinates are determinants:
$$I_{1} = a_{11} + a_{22} + a_{33}$$
|a11 a12| |a22 a23| |a11 a13|
I2 = | | + | | + | |
|a12 a22| |a23 a33| |a13 a33|$$I_{3} = \left|\begin{matrix}a_{11} & a_{12} & a_{13}\\a_{12} & a_{22} & a_{23}\\a_{13} & a_{23} & a_{33}\end{matrix}\right|$$
$$I_{4} = \left|\begin{matrix}a_{11} & a_{12} & a_{13} & a_{14}\\a_{12} & a_{22} & a_{23} & a_{24}\\a_{13} & a_{23} & a_{33} & a_{34}\\a_{14} & a_{24} & a_{34} & a_{44}\end{matrix}\right|$$
$$I{\left(\lambda \right)} = \left|\begin{matrix}a_{11} - \lambda & a_{12} & a_{13}\\a_{12} & a_{22} - \lambda & a_{23}\\a_{13} & a_{23} & a_{33} - \lambda\end{matrix}\right|$$
|a11 a14| |a22 a24| |a33 a34|
K2 = | | + | | + | |
|a14 a44| |a24 a44| |a34 a44| |a11 a12 a14| |a22 a23 a24| |a11 a13 a14|
| | | | | |
K3 = |a12 a22 a24| + |a23 a33 a34| + |a13 a33 a34|
| | | | | |
|a14 a24 a44| |a24 a34 a44| |a14 a34 a44|substitute coefficients
$$I_{1} = 6$$
|2 1| |2 1| |2 1|
I2 = | | + | | + | |
|1 2| |1 2| |1 2|$$I_{3} = \left|\begin{matrix}2 & 1 & 1\\1 & 2 & 1\\1 & 1 & 2\end{matrix}\right|$$
$$I_{4} = \left|\begin{matrix}2 & 1 & 1 & 0\\1 & 2 & 1 & 0\\1 & 1 & 2 & 0\\0 & 0 & 0 & 0\end{matrix}\right|$$
$$I{\left(\lambda \right)} = \left|\begin{matrix}- \lambda + 2 & 1 & 1\\1 & - \lambda + 2 & 1\\1 & 1 & - \lambda + 2\end{matrix}\right|$$
|2 0| |2 0| |2 0|
K2 = | | + | | + | |
|0 0| |0 0| |0 0| |2 1 0| |2 1 0| |2 1 0|
| | | | | |
K3 = |1 2 0| + |1 2 0| + |1 2 0|
| | | | | |
|0 0 0| |0 0 0| |0 0 0|$$I_{1} = 6$$
$$I_{2} = 9$$
$$I_{3} = 4$$
$$I_{4} = 0$$
$$I{\left(\lambda \right)} = - \lambda^{3} + 6 \lambda^{2} - 9 \lambda + 4$$
$$K_{2} = 0$$
$$K_{3} = 0$$
Because
I3 != 0
then by type of surface:
you need to
Make the characteristic equation for the surface:
$$- I_{1} \lambda^{2} + \lambda^{3} + I_{2} \lambda - I_{3} = 0$$
or
$$\lambda^{3} - 6 \lambda^{2} + 9 \lambda - 4 = 0$$
Solve this equation
$$\lambda_{1} = 4$$
$$\lambda_{2} = 1$$
$$\lambda_{3} = 1$$
then the canonical form of the equation will be
$$\left(\tilde x1^{2} \lambda_{3} + \left(\tilde x2^{2} \lambda_{2} + \tilde x3^{2} \lambda_{1}\right)\right) + \frac{I_{4}}{I_{3}} = 0$$
$$\tilde x1^{2} + \tilde x2^{2} + 4 \tilde x3^{2} = 0$$
$$\frac{\tilde x1^{2}}{1^{2}} + \left(\frac{\tilde x2^{2}}{1^{2}} + \frac{\tilde x3^{2}}{\left(\frac{1}{2}\right)^{2}}\right) = 0$$
this equation is fora type imaginary cone
- reduced to canonical form