matrix calculation reshaping and diferences between datum

Question

Vasco el 2 de En. de 2024

0
Enlazar

Enlace directo a esta pregunta

https://la.mathworks.com/matlabcentral/answers/2065756-matrix-calculation-reshaping-and-diferences-between-datum

Comentada: Cris LaPierre el 4 de En. de 2024

Respuesta aceptada: Cris LaPierre

Coordinate_Systems.m

i dont know how to transform the Z dimension into a 2x2 matriz at least i dont understand how to make it run

7 comentarios
Mostrar 5 comentarios más antiguosOcultar 5 comentarios más antiguos

Voss el 2 de En. de 2024

Where would the country border come from?

I don't know what's going on either; you'll need to step through your code and check that each variable seems reasonable (correct size, reasonable values) as it runs, and find where it goes wrong and fix it.

Vasco el 2 de En. de 2024

i checked the values, the values of the other variables check, i just dont get what is happening maybe is it because the data doesnt come sorted?

the figure im making is an attempt to answer this question :"Assess the differences between ETRS89 and the local datums (D73 and DLx) regarding geodesic coordinates (Δφ, Δλ, Δh)."

Iniciar sesión para comentar.

Iniciar sesión para responder a esta pregunta.

Answer 1

Cris LaPierre el 2 de En. de 2024

0
Enlazar

Enlace directo a esta respuesta

https://la.mathworks.com/matlabcentral/answers/2065756-matrix-calculation-reshaping-and-diferences-between-datum#answer_1381941

Abrir en MATLAB Online

RGN_ETRS89_geod.txt

I'd use scatteredInterpolant probably.

Also, you can simplify your code a little by accessing the data in your tables more directly. See here: https://www.mathworks.com/help/matlab/matlab_prog/access-data-in-a-table.html

Here's the relevant pieces of code. Note that I am not claiming to solve your assignment for you. Just get you started.

%Inserção dos dados e criação de variáveis

file_in=readtable("RGN_ETRS89_geod.txt");

lat_dec = dms2degrees(file_in{:,["Latd","Latm","Lats"]});

lon_dec = -1*dms2degrees(file_in{:,["Lond","Lonm","Lons"]});

alt_orto = file_in.h;

alt_elips = file_in.H;

% scatterm(lat_dec,lon_dec)

k = boundary(lat_dec,lon_dec);

geoshow(lat_dec(k),lon_dec(k))

%Elipsoide de referência para ETRS89: GRS80

a=6378137;

f=1/298.257222101;

b=a*(1-f);

e=(sqrt(a^2-b^2))/a;

N=a./sqrt(1-e^2.*(sind(lat_dec)).^2);

%Cálculo de X, Y e Z

X=(N+alt_elips).*cosd(lat_dec).*cosd(lon_dec);

Y=(N+alt_elips).*cosd(lat_dec).*sind(lon_dec);

Z=(N.*(1-e^2)+alt_elips).*sind(lat_dec);

%Exercício 2

%2.1

Tx=230.994;

Ty=-102.591;

Tz=-25.199;

omegax=deg2rad(-0.633/3600);

omegay=deg2rad(0.239/3600);

omegaz=deg2rad(-0.900/3600);

D=-1.950*10^-6;

matriz=[1 -omegaz omegay; omegaz 1 -omegax; -omegay omegax 1];

for i=1:1668

D73=[Tx;Ty;Tz]+(D+1)*matriz*[X(i);Y(i);Z(i)];

XD73(i,1)=D73(1);

YD73(i,1)=D73(2);

ZD73(i,1)=D73(3);

end

%2.2

Tx=283.088;

Ty=70.693;

Tz=-117.445;

omegax=deg2rad(1.157/3600);

omegay=deg2rad(-0.059/3600);

omegaz=deg2rad(0.652/3600);

D=4.058*10^-6;

matriz=[1 -omegaz omegay; omegaz 1 -omegax; -omegay omegax 1];

for i=1:1668

DLx=[Tx;Ty;Tz]+(D+1)*matriz*[X(i);Y(i);Z(i)];

XDLx(i,1)=DLx(1);

YDLx(i,1)=DLx(2);

ZDLx(i,1)=DLx(3);

end

%Elipsóide de referência para o Datum 73 e Datum Lisboa - Hayford

a_D73= 6378388;

f_D73=1/297;

b_D73=a_D73*(1-f_D73);

e_D73=(sqrt(a_D73^2-b_D73^2))/a_D73;

%Datum Lisboa

%Determinação da latitude

%Estimativa inicial

p=sqrt(XDLx.^2+YDLx.^2);

lat_0=atand(ZDLx./p);

N_0=a_D73./sqrt(1-e_D73^2.*(sind(lat_0)).^2);

%Primeira iteração

lat_1=atand((ZDLx+e_D73^2.*N_0.*sind(lat_0))./p);

N_1=a_D73./sqrt(1-e_D73^2.*(sind(lat_1)).^2);

%Segunda iteração

lat_2=atand((ZDLx+e_D73^2.*N_1.*sind(lat_1))./p);

N_2=a_D73./sqrt(1-e_D73^2.*(sind(lat_2)).^2);

%Terceira iteração

lat_3_DLx=atand((ZDLx+e_D73^2.*N_2.*sind(lat_2))./p);

%DLX figura e D73 figura

delta_lat_Dlx = lat_dec - lat_3_DLx;

% Create a function for predicting delta_lat_Dlx based on lat & lon data

F = scatteredInterpolant(lon_dec,lat_dec,delta_lat_Dlx);

% Create a 2d grid of Lat and Lon values

[LON,LAT] = meshgrid(-10:0.1:-6,36:0.05:43);

% Predict gridded values for delta_lat_Dlx

Z = F(LON,LAT);

% set values outside portugal to nan (so they do not appear in contour plot

in = inpolygon(LAT,LON,lat_dec(k),lon_dec(k));

Z(~in) = nan;

% Create a contour plot

hold on

contourm(LAT,LON,Z,10,'r','ShowText','on')

hold off

6 comentarios
Mostrar 4 comentarios más antiguosOcultar 4 comentarios más antiguos

Vasco el 3 de En. de 2024

Editada: Cris LaPierre el 3 de En. de 2024

Abrir en MATLAB Online

First of all thank you for your suport.

I tried doing it for the lat, lon and h

the figure appears but the limits of the country dont Im gonna send the full code again if you could help me fix the problem, it would be live saving.

close all;

clear all;

clc;

%Exercício 1

%Inserção dos dados e criação de variáveis

file_in=readtable("RGN_ETRS89_geod.txt");

lat_dec = dms2degrees(file_in{:,["Latd","Latm","Lats"]});

lon_dec = -1*dms2degrees(file_in{:,["Lond","Lonm","Lons"]});

alt_orto = file_in.h;

alt_elips = file_in.H;

%Transformação dos dados em decimais

k = boundary(lat_dec,lon_dec);

geoshow(lat_dec(k),lon_dec(k));

%Elipsoide de referência para ETRS89: GRS80

a=6378137;

f=1/298.257222101;

b=a*(1-f);

e=(sqrt(a^2-b^2))/a;

%Cálculo de N (grande normal)

N=a./sqrt(1-e^2.*(sind(lat_dec)).^2);

%Cálculo de X, Y e Z

X=(N+alt_elips).*cosd(lat_dec).*cosd(lon_dec);

Y=(N+alt_elips).*cosd(lat_dec).*sind(lon_dec);

Z=(N.*(1-e^2)+alt_elips).*sind(lat_dec);

%%

%Exercício 2

%2.1

Tx=230.994;

Ty=-102.591;

Tz=-25.199;

omegax=deg2rad(-0.633/3600);

omegay=deg2rad(0.239/3600);

omegaz=deg2rad(-0.900/3600);

D=-1.950*10^-6;

matriz=[1 -omegaz omegay; omegaz 1 -omegax; -omegay omegax 1];

for i=1:1668

D73=[Tx;Ty;Tz]+(D+1)*matriz*[X(i);Y(i);Z(i)];

XD73(i,1)=D73(1);

YD73(i,1)=D73(2);

ZD73(i,1)=D73(3);

end

%%

%2.2

Tx=283.088;

Ty=70.693;

Tz=-117.445;

omegax=deg2rad(1.157/3600);

omegay=deg2rad(-0.059/3600);

omegaz=deg2rad(0.652/3600);

D=4.058*10^-6;

matriz=[1 -omegaz omegay; omegaz 1 -omegax; -omegay omegax 1];

for i=1:1668

DLx=[Tx;Ty;Tz]+(D+1)*matriz*[X(i);Y(i);Z(i)];

XDLx(i,1)=DLx(1);

YDLx(i,1)=DLx(2);

ZDLx(i,1)=DLx(3);

end

%%

%Elipsóide de referência para o Datum 73 e Datum Lisboa - Hayford

a_D73= 6378388;

f_D73=1/297;

b_D73=a_D73*(1-f_D73);

e_D73=(sqrt(a_D73^2-b_D73^2))/a_D73;

%Cálculo da longitude

lon_D73=atand(YD73(:,1)./XD73(:,1));

%Determinação da latitude

%Estimativa inicial

p=sqrt((XD73(:,1)).^2+(YD73(:,1)).^2);

lat_0_73=atand(ZD73(:,1)./p);

N_0_73=a_D73./sqrt(1-e_D73^2.*(sind(lat_0_73)).^2);

%Primeira iteração

lat_1_73=atand((ZD73(:,1)+e_D73^2.*N_0_73.*sind(lat_0_73))./p);

N_1_73=a_D73./sqrt(1-e_D73^2.*(sind(lat_1_73)).^2);

%Segunda iteração

lat_2_73=atand((ZD73(:,1)+e_D73^2.*N_1_73.*sind(lat_1_73))./p);

N_2_73=a_D73./sqrt(1-e_D73^2.*(sind(lat_2_73)).^2);

%Terceira iteração

lat_3_D73=atand((ZD73(:,1)+e_D73^2.*N_2_73.*sind(lat_2_73))./p);

N_3_73=a_D73./sqrt(1-e_D73^2.*(sind(lat_3_D73)).^2);

%Os valores já não se alteram da segunda para a terceira iteração, fazendo

%desta a que fornece o valor definitivo da latitude.

%Cálculo de h

h_D73=(p./cosd(lat_3_D73))-N_3_73;

%%

%Datum Lisboa

%Cálculo da longitude

lon_DLx=atand(YDLx./XDLx);

%Determinação da latitude

%Estimativa inicial

p=sqrt(XDLx.^2+YDLx.^2);

lat_0_lx=atand(ZDLx./p);

N_0_lx=a_D73./sqrt(1-e_D73^2.*(sind(lat_0_lx)).^2);

%Primeira iteração

lat_1_lx=atand((ZDLx+e_D73^2.*N_0_lx.*sind(lat_0_lx))./p);

N_1_lx=a_D73./sqrt(1-e_D73^2.*(sind(lat_1_lx)).^2);

%Segunda iteração

lat_2_lx=atand((ZDLx+e_D73^2.*N_1_lx.*sind(lat_1_lx))./p);

N_2_lx=a_D73./sqrt(1-e_D73^2.*(sind(lat_2_lx)).^2);

%Terceira iteração

lat_3_DLx=atand((ZDLx+e_D73^2.*N_2_lx.*sind(lat_2_lx))./p);

N_3_lx=a_D73./sqrt(1-e_D73^2.*(sind(lat_3_DLx)).^2);

%Os valores já não se alteram da segunda para a terceira iteração, fazendo

%desta a que fornece o valor definitivo da latitude.

%Cálculo de h

h_DLx=(p./cosd(lat_3_DLx))-N_3_lx;

%%

%----------------

%----- etrs89 and datum lisboa

%DLX figura e D73 figura

delta_lat_Dlx = (lat_dec - lat_3_DLx).*3600;

delta_lon_Dlx = (lon_dec - lon_D73).*3600;

delta_h_Dlx = (alt_elips-h_D73);

%%

figure(1);

% Create a function for predicting delta_lat_Dlx based on lat & lon data

F = scatteredInterpolant(lon_dec,lat_dec,delta_lat_Dlx);

% Create a 2d grid of Lat and Lon values

[LON,LAT] = meshgrid(-10:0.1:-6,36:0.05:43);

% Predict gridded values for delta_lat_Dlx

Z = F(LON,LAT);

% set values outside portugal to nan (so they do not appear in contour plot

in = inpolygon(LAT,LON,lat_dec(k),lon_dec(k));

Z(~in) = nan;

% Create a contour plot

hold on

contourm(LAT,LON,Z,10,'r','ShowText','on')

hold off

%%

figure(2);

% Create a function for predicting delta_lat_Dlx based on lat & lon data

G = scatteredInterpolant(lon_dec,lat_dec,delta_lon_Dlx);

% Create a 2d grid of Lat and Lon values

[LON_1,LAT_1] = meshgrid(-10:0.1:-6,36:0.05:43);

% Predict gridded values for delta_lat_Dlx

V = G(LON_1,LAT_1);

% set values outside portugal to nan (so they do not appear in contour plot

in_1 = inpolygon(LAT_1,LON_1,lat_dec(k),lon_dec(k));

V(~in_1) = nan;

% Create a contour plot

hold on

contourm(LAT_1,LON_1,V,10,'r','ShowText','on')

hold off

%%

figure(3);

% Create a function for predicting delta_lat_Dlx based on lat & lon data

L = scatteredInterpolant(lon_dec,lat_dec,delta_h_Dlx);

% Create a 2d grid of Lat and Lon values

[LON_2,LAT_2] = meshgrid(-10:0.1:-6,36:0.05:43);

% Predict gridded values for delta_lat_Dlx

O = L(LON_2,LAT_2);

% set values outside portugal to nan (so they do not appear in contour plot

in = inpolygon(LAT_2,LON_2,lat_dec(k),lon_dec(k));

O(~in_2) = nan;

Unrecognized function or variable 'in_2'.

% Create a contour plot

hold on

contourm(LAT_2,LON_2,O,10,'r','ShowText','on')

hold off

Vasco el 3 de En. de 2024

thank you very much its fixed

i try to do it with subplot but theres some type of error because it loads the lines but it doesnt load the values nor the borders.

Cris LaPierre el 4 de En. de 2024

I wouldn't expect subplot to fix the issue. Please try what I suggested.

Iniciar sesión para comentar.

matrix calculation reshaping and diferences between datum

7 comentarios
Mostrar 5 comentarios más antiguosOcultar 5 comentarios más antiguos

Respuesta aceptada

6 comentarios
Mostrar 4 comentarios más antiguosOcultar 4 comentarios más antiguos

Más respuestas (0)

Ver también

Categorías

Etiquetas

Community Treasure Hunt

matrix calculation reshaping and diferences between datum

7 comentarios Mostrar 5 comentarios más antiguosOcultar 5 comentarios más antiguos

Respuesta aceptada

6 comentarios Mostrar 4 comentarios más antiguosOcultar 4 comentarios más antiguos

Más respuestas (0)

Ver también

Categorías

Etiquetas

Community Treasure Hunt

7 comentarios
Mostrar 5 comentarios más antiguosOcultar 5 comentarios más antiguos

6 comentarios
Mostrar 4 comentarios más antiguosOcultar 4 comentarios más antiguos