Difference between revisions of "Coordinate systems"
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| + | ==Convention for Cartesian coordinates== | ||
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| + | *Middle of the sphere is (0, 0, 0) | ||
| + | *X is left (-) to right (+) | ||
| + | *Y is back (-) to front (+) | ||
| + | *Z is bottom (-) to top (+) | ||
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| + | The convention for head tracking coordinates is equal to Cartesian coordinates | ||
| + | *Horizontal = X | ||
| + | *Frontal = Y | ||
| + | *Vertical = Z | ||
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| + | ==Convention for spherical coordinates== | ||
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| + | ==Convention for double polar coordinates== | ||
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| + | % azimuth is angle (in rad) with YZ plane with Y-hat is zero and X-hat is | ||
| + | % pi/2. | ||
| + | % elevation is angle (in rad) with XY plane with Y-hat is zero Z-hat is | ||
| + | % pi/2. | ||
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| + | ==Conversion from Cartesian to Double Polar== | ||
| + | % Double polar coördinates is a non-standard coördinate system used for audiological purposes only. | ||
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| + | The procedure for transformation is the following: | ||
| + | *1 Project the Cartesian coordinates to the XY-plane. | ||
| + | *2 This forms a two dimensional vector in the XY-plane. | ||
| + | *3 Take the angle of this vector with the Y-hat. This is the azimuth. | ||
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| + | Project the Cartesian coordinates to the YZ-plane. | ||
| + | Take the angle of this vector with the Y-hat. This is the elevation. | ||
| + | Angles larger than pi/2 are folded back by mirroring | ||
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| + | === | ||
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| + | The algorith uses the inverse of: dotproduct(V1,V2) = | ||
| + | |V1|*|V2|*cos(angle) to determine the angle. | ||
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<pre> | <pre> | ||
% This function converts cartesian coördinates X, Y, Z to double polar coördinates (r, elevation, azimuth) | % This function converts cartesian coördinates X, Y, Z to double polar coördinates (r, elevation, azimuth) | ||
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% | % | ||
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% To calculate the angle with a plane the dotproduct with the normal of the plane is calculated first. | % To calculate the angle with a plane the dotproduct with the normal of the plane is calculated first. | ||
% The angle with the plane is pi/2 - angle with normal. | % The angle with the plane is pi/2 - angle with normal. | ||
% One also needs to take the quadrant into consideration. | % One also needs to take the quadrant into consideration. | ||
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function [azimuth, elevation, r] = cart2double_polar(X, Y, Z) | function [azimuth, elevation, r] = cart2double_polar(X, Y, Z) | ||
Revision as of 14:43, 14 February 2024
Convention for Cartesian coordinates
- Middle of the sphere is (0, 0, 0)
- X is left (-) to right (+)
- Y is back (-) to front (+)
- Z is bottom (-) to top (+)
The convention for head tracking coordinates is equal to Cartesian coordinates
- Horizontal = X
- Frontal = Y
- Vertical = Z
Convention for spherical coordinates
Convention for double polar coordinates
% azimuth is angle (in rad) with YZ plane with Y-hat is zero and X-hat is % pi/2. % elevation is angle (in rad) with XY plane with Y-hat is zero Z-hat is % pi/2.
Conversion from Cartesian to Double Polar
% Double polar coördinates is a non-standard coördinate system used for audiological purposes only.
The procedure for transformation is the following:
- 1 Project the Cartesian coordinates to the XY-plane.
- 2 This forms a two dimensional vector in the XY-plane.
- 3 Take the angle of this vector with the Y-hat. This is the azimuth.
Project the Cartesian coordinates to the YZ-plane. Take the angle of this vector with the Y-hat. This is the elevation. Angles larger than pi/2 are folded back by mirroring
=
The algorith uses the inverse of: dotproduct(V1,V2) = |V1|*|V2|*cos(angle) to determine the angle.
% This function converts cartesian coördinates X, Y, Z to double polar coördinates (r, elevation, azimuth)
%
% To calculate the angle with a plane the dotproduct with the normal of the plane is calculated first.
% The angle with the plane is pi/2 - angle with normal.
% One also needs to take the quadrant into consideration.
function [azimuth, elevation, r] = cart2double_polar(X, Y, Z)
r = sqrt(X^2+Y^2+Z^2);
%azimuth: projection to XY plane, angle with Y_hat
az_angleWithY_hat = getAngle([X,Y,0],[0,1,0]);
%elevation: projection to YZ plane, angle with Y_hat
el_angleWithY_hat = getAngle([0,Y,Z],[0,1,0]);
% azimuth from -pi to +pi
switch findQuadrant(X, Y) % Quadrants are numbered anti-clockwise
case {1,4}
azimuth = az_angleWithY_hat;
case {2, 3}
azimuth = - az_angleWithY_hat;
case 0 % (X=0 or Y=0)
azimuth = 0;
end
% elevation from -pi/2 to +pi/2
switch findQuadrant(Y, Z)
case 1
elevation = el_angleWithY_hat;
case 2
elevation = pi - el_angleWithY_hat;
case 3
elevation = el_angleWithY_hat - pi;
case 4
elevation = - el_angleWithY_hat;
case 0 % (Y=0 or Z=0)
elevation = 0;
end