Geometric norm: Difference between revisions
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== Bulk Norm == | == Bulk Norm == | ||
The ''bulk norm'' of an element $$\mathbf | The ''bulk norm'' of an element $$\mathbf u$$, denoted $$\left\Vert\mathbf u\right\Vert_\unicode{x25CF}$$, is the magnitude of its [[bulk]] components. It can be calculated by taking the square root of the [[dot product]] of $$\mathbf u$$ with itself: | ||
:$$\left\Vert\mathbf | :$$\left\Vert\mathbf u\right\Vert_\unicode{x25CF} = \sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u}$$ . | ||
An element that has a bulk norm of '''1''' is said to be ''bulk normalized''. | An element that has a bulk norm of '''1''' is said to be ''bulk normalized''. | ||
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== Weight Norm == | == Weight Norm == | ||
The ''weight norm'' of an element $$\mathbf | The ''weight norm'' of an element $$\mathbf u$$, denoted $$\left\Vert\mathbf u\right\Vert_\unicode{x25CB}$$, is the magnitude of its [[weight]] components. It can be calculated by taking the square root of the [[antidot product]] of $$\mathbf u$$ with itself: | ||
:$$\left\Vert\mathbf | :$$\left\Vert\mathbf u\right\Vert_\unicode{x25CB} = \sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}$$ . | ||
(Note that the square root in this case is taken with respect to the geometric antiproduct.) | (Note that the square root in this case is taken with respect to the geometric antiproduct.) | ||
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The bulk norm and weight norm are summed to construct the ''geometric norm'' given by | The bulk norm and weight norm are summed to construct the ''geometric norm'' given by | ||
:$$\left\Vert\mathbf | :$$\left\Vert\mathbf u\right\Vert = \left\Vert\mathbf u\right\Vert_\unicode{x25CF} + \left\Vert\mathbf u\right\Vert_\unicode{x25CB} = \sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u} + \sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}$$ . | ||
This quantity is the sum of a scalar $$a\mathbf 1$$ and antiscalar $$b{\large\unicode{x1D7D9}}$$ representing a ''homogeneous magnitude'' that itself has a bulk and a weight. Its bulk norm is simply the magnitude of its scalar part, and its weight norm is simply the magnitude of its antiscalar part. The geometric norm is idempotent because | This quantity is the sum of a scalar $$a\mathbf 1$$ and antiscalar $$b{\large\unicode{x1D7D9}}$$ representing a ''homogeneous magnitude'' that itself has a bulk and a weight. Its bulk norm is simply the magnitude of its scalar part, and its weight norm is simply the magnitude of its antiscalar part. The geometric norm is idempotent because | ||
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:$$\left\Vert a\mathbf 1 + b{\large\unicode{x1D7D9}}\right\Vert = |a|\mathbf 1 + |b|{\large\unicode{x1D7D9}}$$ . | :$$\left\Vert a\mathbf 1 + b{\large\unicode{x1D7D9}}\right\Vert = |a|\mathbf 1 + |b|{\large\unicode{x1D7D9}}$$ . | ||
Like all other homogeneous quantities, the magnitude given by the geometric norm is [[unitized]] by dividing by its weight norm. The unitized magnitude of an element $$\mathbf | Like all other homogeneous quantities, the magnitude given by the geometric norm is [[unitized]] by dividing by its weight norm. The unitized magnitude of an element $$\mathbf u$$ is given by | ||
:$$\widehat{\left\Vert\mathbf | :$$\widehat{\left\Vert\mathbf u\right\Vert} = \dfrac{\left\Vert\mathbf u\right\Vert}{\left\Vert\mathbf u\right\Vert_\unicode{x25CB}} = \dfrac{\left\Vert\mathbf u\right\Vert_\unicode{x25CF}}{\left\Vert\mathbf u\right\Vert_\unicode{x25CB}} + {\large\unicode{x1D7D9}} = \dfrac{\sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u}}{\sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}} + {\large\unicode{x1D7D9}}$$ . | ||
The following table lists the unitized geometric norms of the main types in the 4D rigid geometric algebra $$\mathcal G_{3,0,1}$$ after dropping the constant $${\large\unicode{x1D7D9}}$$ term. | The following table lists the unitized geometric norms of the main types in the 4D rigid geometric algebra $$\mathcal G_{3,0,1}$$ after dropping the constant $${\large\unicode{x1D7D9}}$$ term. |
Revision as of 07:23, 23 October 2023
The geometric norm is a measure of the magnitude of an element. It has two components called the bulk norm and the weight norm.
For points, lines, and planes, the geometric norm is equal to the shortest Euclidean distance between the geometry and the origin. For motors and flectors, the geometric norm is equal to half the distance that the origin is moved by the isometry operator.
Bulk Norm
The bulk norm of an element $$\mathbf u$$, denoted $$\left\Vert\mathbf u\right\Vert_\unicode{x25CF}$$, is the magnitude of its bulk components. It can be calculated by taking the square root of the dot product of $$\mathbf u$$ with itself:
- $$\left\Vert\mathbf u\right\Vert_\unicode{x25CF} = \sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u}$$ .
An element that has a bulk norm of 1 is said to be bulk normalized.
The following table lists the bulk norms of the main types in the 4D rigid geometric algebra $$\mathcal G_{3,0,1}$$.
Type | Definition | Bulk Norm |
---|---|---|
Magnitude | $$\mathbf z = x \mathbf 1 + y {\large\unicode{x1d7d9}}$$ | $$\left\Vert\mathbf z\right\Vert_\unicode{x25CF} = |x|$$ |
Point | $$\mathbf p = p_x \mathbf e_1 + p_y \mathbf e_2 + p_z \mathbf e_3 + p_w \mathbf e_4$$ | $$\left\Vert\mathbf p\right\Vert_\unicode{x25CF} = \sqrt{p_x^2 + p_y^2 + p_z^2}$$ |
Line | $$\boldsymbol l = l_{vx} \mathbf e_{41} + l_{vy} \mathbf e_{42} + l_{vz} \mathbf e_{43} + l_{mx} \mathbf e_{23} + l_{my} \mathbf e_{31} + l_{mz} \mathbf e_{12}$$ | $$\left\Vert\boldsymbol l\right\Vert_\unicode{x25CF} = \sqrt{l_{mx}^2 + l_{my}^2 + l_{mz}^2}$$ |
Plane | $$\mathbf g = g_x \mathbf e_{423} + g_y \mathbf e_{431} + g_z \mathbf e_{412} + g_w \mathbf e_{321}$$ | $$\left\Vert\mathbf g\right\Vert_\unicode{x25CF} = |g_w|$$ |
Motor | $$\mathbf Q = Q_{vx} \mathbf e_{41} + Q_{vy} \mathbf e_{42} + Q_{vz} \mathbf e_{43} + Q_{vw} {\large\unicode{x1d7d9}} + Q_{mx} \mathbf e_{23} + Q_{my} \mathbf e_{31} + Q_{mz} \mathbf e_{12} + Q_{mw} \mathbf 1$$ | $$\left\Vert\mathbf Q\right\Vert_\unicode{x25CF} = \sqrt{Q_{mx}^2 + Q_{my}^2 + Q_{mz}^2 + Q_{mw}^2}$$ |
Flector | $$\mathbf F = F_{px} \mathbf e_1 + F_{py} \mathbf e_2 + F_{pz} \mathbf e_3 + F_{pw} \mathbf e_4 + F_{gx} \mathbf e_{423} + F_{gy} \mathbf e_{431} + F_{gz} \mathbf e_{412} + F_{gw} \mathbf e_{321}$$ | $$\left\Vert\mathbf F\right\Vert_\unicode{x25CF} = \sqrt{F_{px}^2 + F_{py}^2 + F_{pz}^2 + F_{gw}^2}$$ |
Weight Norm
The weight norm of an element $$\mathbf u$$, denoted $$\left\Vert\mathbf u\right\Vert_\unicode{x25CB}$$, is the magnitude of its weight components. It can be calculated by taking the square root of the antidot product of $$\mathbf u$$ with itself:
- $$\left\Vert\mathbf u\right\Vert_\unicode{x25CB} = \sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}$$ .
(Note that the square root in this case is taken with respect to the geometric antiproduct.)
An element that has a weight norm of $$\large\unicode{x1D7D9}$$ is said to be weight normalized or unitized.
The following table lists the weight norms of the main types in the 4D rigid geometric algebra $$\mathcal G_{3,0,1}$$.
Type | Definition | Weight Norm |
---|---|---|
Magnitude | $$\mathbf z = x \mathbf 1 + y {\large\unicode{x1d7d9}}$$ | $$\left\Vert\mathbf z\right\Vert_\unicode{x25CB} = |y|{\large\unicode{x1D7D9}}$$ |
Point | $$\mathbf p = p_x \mathbf e_1 + p_y \mathbf e_2 + p_z \mathbf e_3 + p_w \mathbf e_4$$ | $$\left\Vert\mathbf p\right\Vert_\unicode{x25CB} = |p_w|{\large\unicode{x1D7D9}}$$ |
Line | $$\boldsymbol l = l_{vx} \mathbf e_{41} + l_{vy} \mathbf e_{42} + l_{vz} \mathbf e_{43} + l_{mx} \mathbf e_{23} + l_{my} \mathbf e_{31} + l_{mz} \mathbf e_{12}$$ | $$\left\Vert\boldsymbol l\right\Vert_\unicode{x25CB} = {\large\unicode{x1D7D9}}\sqrt{l_{vx}^2 + l_{vy}^2 + l_{vz}^2}$$ |
Plane | $$\mathbf g = g_x \mathbf e_{234} + g_y \mathbf e_{314} + g_z \mathbf e_{124} + g_w \mathbf e_{321}$$ | $$\left\Vert\mathbf g\right\Vert_\unicode{x25CB} = {\large\unicode{x1D7D9}}\sqrt{g_x^2 + g_y^2 + g_z^2}$$ |
Motor | $$\mathbf Q = Q_{vx} \mathbf e_{41} + Q_{vy} \mathbf e_{42} + Q_{vz} \mathbf e_{43} + Q_{vw} {\large\unicode{x1d7d9}} + Q_{mx} \mathbf e_{23} + Q_{my} \mathbf e_{31} + Q_{mz} \mathbf e_{12} + Q_{mw} \mathbf 1$$ | $$\left\Vert\mathbf Q\right\Vert_\unicode{x25CB} = {\large\unicode{x1D7D9}}\sqrt{Q_{vx}^2 + Q_{vy}^2 + Q_{vz}^2 + Q_{vw}^2}$$ |
Flector | $$\mathbf F = F_{px} \mathbf e_1 + F_{py} \mathbf e_2 + F_{pz} \mathbf e_3 + F_{pw} \mathbf e_4 + F_{gx} \mathbf e_{423} + F_{gy} \mathbf e_{431} + F_{gz} \mathbf e_{412} + F_{gw} \mathbf e_{321}$$ | $$\left\Vert\mathbf F\right\Vert_\unicode{x25CB} = {\large\unicode{x1D7D9}}\sqrt{F_{gx}^2 + F_{gy}^2 + F_{gz}^2 + F_{pw}^2}$$ |
Geometric Norm
The bulk norm and weight norm are summed to construct the geometric norm given by
- $$\left\Vert\mathbf u\right\Vert = \left\Vert\mathbf u\right\Vert_\unicode{x25CF} + \left\Vert\mathbf u\right\Vert_\unicode{x25CB} = \sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u} + \sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}$$ .
This quantity is the sum of a scalar $$a\mathbf 1$$ and antiscalar $$b{\large\unicode{x1D7D9}}$$ representing a homogeneous magnitude that itself has a bulk and a weight. Its bulk norm is simply the magnitude of its scalar part, and its weight norm is simply the magnitude of its antiscalar part. The geometric norm is idempotent because
- $$\left\Vert a\mathbf 1 + b{\large\unicode{x1D7D9}}\right\Vert = |a|\mathbf 1 + |b|{\large\unicode{x1D7D9}}$$ .
Like all other homogeneous quantities, the magnitude given by the geometric norm is unitized by dividing by its weight norm. The unitized magnitude of an element $$\mathbf u$$ is given by
- $$\widehat{\left\Vert\mathbf u\right\Vert} = \dfrac{\left\Vert\mathbf u\right\Vert}{\left\Vert\mathbf u\right\Vert_\unicode{x25CB}} = \dfrac{\left\Vert\mathbf u\right\Vert_\unicode{x25CF}}{\left\Vert\mathbf u\right\Vert_\unicode{x25CB}} + {\large\unicode{x1D7D9}} = \dfrac{\sqrt{\mathbf u \mathbin{\unicode{x25CF}} \mathbf u}}{\sqrt{\mathbf u \mathbin{\unicode{x25CB}} \mathbf u}} + {\large\unicode{x1D7D9}}$$ .
The following table lists the unitized geometric norms of the main types in the 4D rigid geometric algebra $$\mathcal G_{3,0,1}$$ after dropping the constant $${\large\unicode{x1D7D9}}$$ term.
Type | Definition | Geometric Norm | Interpretation |
---|---|---|---|
Magnitude | $$\mathbf z = x \mathbf 1 + y {\large\unicode{x1d7d9}}$$ | $$\widehat{\left\Vert\mathbf z\right\Vert} = \dfrac{|x|}{|y|}$$ | A Euclidean distance. |
Point | $$\mathbf p = p_x \mathbf e_1 + p_y \mathbf e_2 + p_z \mathbf e_3 + p_w \mathbf e_4$$ | $$\widehat{\left\Vert\mathbf p\right\Vert} = \dfrac{\sqrt{p_x^2 + p_y^2 + p_z^2}}{|p_w|}$$ | Distance from the origin to the point $$\mathbf p$$.
Half the distance that the origin is moved by the flector $$\mathbf p$$. |
Line | $$\boldsymbol l = l_{vx} \mathbf e_{41} + l_{vy} \mathbf e_{42} + l_{vz} \mathbf e_{43} + l_{mx} \mathbf e_{23} + l_{my} \mathbf e_{31} + l_{mz} \mathbf e_{12}$$ | $$\widehat{\left\Vert\boldsymbol l\right\Vert} = \sqrt{\dfrac{l_{mx}^2 + l_{my}^2 + l_{mz}^2}{l_{vx}^2 + l_{vy}^2 + l_{vz}^2}}$$ | Perpendicular distance from the origin to the line $$\boldsymbol l$$.
Half the distance that the origin is moved by the motor $$\boldsymbol l$$. |
Plane | $$\mathbf g = g_x \mathbf e_{423} + g_y \mathbf e_{431} + g_z \mathbf e_{412} + g_w \mathbf e_{321}$$ | $$\widehat{\left\Vert\mathbf g\right\Vert} = \dfrac{|g_w|}{\sqrt{g_x^2 + g_y^2 + g_z^2}}$$ | Perpendicular distance from the origin to the plane $$\mathbf g$$.
Half the distance that the origin is moved by the flector $$\mathbf g$$. |
Motor | $$\mathbf Q = Q_{vx} \mathbf e_{41} + Q_{vy} \mathbf e_{42} + Q_{vz} \mathbf e_{43} + Q_{vw} {\large\unicode{x1d7d9}} + Q_{mx} \mathbf e_{23} + Q_{my} \mathbf e_{31} + Q_{mz} \mathbf e_{12} + Q_{mw} \mathbf 1$$ | $$\widehat{\left\Vert\mathbf Q\right\Vert} = \sqrt{\dfrac{Q_{mx}^2 + Q_{my}^2 + Q_{mz}^2 + Q_{mw}^2}{Q_{vx}^2 + Q_{vy}^2 + Q_{vz}^2 + Q_{vw}^2}}$$ | Half the distance that the origin is moved by the motor $$\mathbf Q$$. |
Flector | $$\mathbf F = F_{px} \mathbf e_1 + F_{py} \mathbf e_2 + F_{pz} \mathbf e_3 + F_{pw} \mathbf e_4 + F_{gx} \mathbf e_{423} + F_{gy} \mathbf e_{431} + F_{gz} \mathbf e_{412} + F_{gw} \mathbf e_{321}$$ | $$\widehat{\left\Vert\mathbf F\right\Vert} = \sqrt{\dfrac{F_{px}^2 + F_{py}^2 + F_{pz}^2 + F_{gw}^2}{F_{gx}^2 + F_{gy}^2 + F_{gz}^2 + F_{pw}^2}}$$ | Half the distance that the origin is moved by the flector $$\mathbf F$$. |