How to solve 3 TDOA equations with 3 variables x,y,z

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Ebrahim Abdullah Ahmed Albabakri
Ebrahim Abdullah Ahmed Albabakri el 21 de En. de 2022
Editada: Torsten el 22 de Nov. de 2023
I have a set of equations which looks like that, how to find x,y,z by coding while all other variables are known?
  2 comentarios
ming
ming el 1 de Ag. de 2023
这个python函数的实现方式是?
Torsten
Torsten el 1 de Ag. de 2023
哪個 python 函數?

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Torsten
Torsten el 21 de En. de 2022
Ran in:
Code for symbolic solution:
syms x y z
x1 = 0.60; y1 = 0.00; z1 = 0.70;
x2 = 0.20; y2 = 1.30; z2 = 0.70;
x3 = 0.80; y3 = 1.05; z3 = 0.20;
x4 = 0.00; y4 = 0.25; z4 = 0.20;
a = 0.19845; b = 0.08791; c = 0.11492;
eqn1 = a==sqrt((x-x2)^2+(y-y2)^2+(z-z2)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn2 = b==sqrt((x-x3)^2+(y-y3)^2+(z-z3)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn3 = c==sqrt((x-x4)^2+(y-y4)^2+(z-z4)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
S = solve([eqn1,eqn2,eqn3],[x,y,z])
S = struct with fields:
x: (193873*83486204818584396915878923974835^(1/2))/17900867984687600000000 + 2237507060134434351121/5594021245214875000000 y: 29092239452758845515869/44752169961719000000000 - (36989*83486204818584396915878923974835^(1/2))/4475216996171900000000 z: (3723*83486204818584396915878923974835^(1/2))/11188042490429750000000 + 417333164652058423709/716034719387504000000
xnum = double(S.x)
xnum = 0.4989
ynum = double(S.y)
ynum = 0.5746
znum = double(S.z)
znum = 0.5859
Code for fsolve:
X0 = [1,1,1];
x1 = 0.60; y1 = 0.00; z1 = 0.70;
x2 = 0.20; y2 = 1.30; z2 = 0.70;
x3 = 0.80; y3 = 1.05; z3 = 0.20;
x4 = 0.00; y4 = 0.25; z4 = 0.20;
a = 0.19845; b = 0.08791; c = 0.11492;
fun=@(x,y,z)[a-(sqrt((x-x2)^2+(y-y2)^2+(z-z2)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2)), ...
b-(sqrt((x-x3)^2+(y-y3)^2+(z-z3)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2)), ...
c-(sqrt((x-x4)^2+(y-y4)^2+(z-z4)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2))];
X = fsolve(@(x)fun(x(1),x(2),x(3)),X0);
Equation solved. fsolve completed because the vector of function values is near zero as measured by the value of the function tolerance, and the problem appears regular as measured by the gradient.
x = X(1)
x = 0.4989
y = X(2)
y = 0.5746
z = X(3)
z = 0.5859
  2 comentarios
Venkata Naresh
Venkata Naresh el 22 de Nov. de 2023
Hi, In the code you provided, what does the values a = 0.19845; b = 0.08791; c = 0.11492;
mean
Torsten
Torsten el 22 de Nov. de 2023
Editada: Torsten el 22 de Nov. de 2023
You are given four points X1, X2, X3 and X4 in three-dimensional space.
You search for a fifth point X for which
the distance difference between (X and X2) and (X and X1) is "a"
the distance difference between (X and X3) and (X and X1) is "b"
the distance difference between (X and X4) and (X and X1) is "c"
Here, a, b and c are given values.
I don't know the application behind this problem, maybe in surveying and mapping.
If you are interested, you should google "TDOA equations" from the title of the message.

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Más respuestas (1)

Torsten
Torsten el 21 de En. de 2022
If there are no specialized methods to solve the TDOA equations (did you take a look into the literature ?), I suggest trying
syms x1 x2 x3 x4 y1 y2 y3 y4 z1 z2 z3 z4 x y z a b c
eqn1 = a==sqrt((x-x2)^2+(y-y2)^2+(z-z2)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn2 = b==sqrt((x-x3)^2+(y-y3)^2+(z-z3)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn3 = c==sqrt((x-x4)^2+(y-y4)^2+(z-z4)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
S = solve([eqn1,eqn2,eqn3],[x,y,z])
If this is not successful, use "fsolve".
  3 comentarios
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Torsten
Torsten el 21 de En. de 2022
Then follow the two ways I gave you.
Ebrahim Abdullah Ahmed Albabakri
Ebrahim Abdullah Ahmed Albabakri el 21 de En. de 2022
This is the output of solve
S =
struct with fields:
x: [1×1 sym]
y: [1×1 sym]
z: [1×1 sym]
fsolve shows an error
Error using fsolve (line 180)
FSOLVE requires the following inputs to be of data type double: 'X0'.
and This is the code
syms x1 x2 x3 x4 y1 y2 y3 y4 z1 z2 z3 z4 x y z a b c
x1 = 0.60; y1 = 0.00; z1 = 0.70;
x2 = 0.20; y2 = 1.30; z2 = 0.70;
x3 = 0.80; y3 = 1.05; z3 = 0.20;
x4 = 0.00; y4 = 0.25; z4 = 0.20;
a = 0.19845; b = 0.08791; c = 0.11492;
eqn1 = a==sqrt((x-x2)^2+(y-y2)^2+(z-z2)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn2 = b==sqrt((x-x3)^2+(y-y3)^2+(z-z3)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
eqn3 = c==sqrt((x-x4)^2+(y-y4)^2+(z-z4)^2) - sqrt((x-x1)^2+(y-y1)^2+(z-z1)^2);
S = solve([eqn1,eqn2,eqn3],[x,y,z])

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