The following code aims to map out the solar system by incorporating every significant body's effect on the others. Of course it should result in expected orbits. In the final embedded function `GravityDE`

it cannot read the values from `PlanetVec`

and, because of that, cannot produce the correct new results each time. We get the error

```
??? Undefined function 'GravityDE' for input arguments of type double.
```

Any suggestions for how to solve this would be most welcome!

```
function Gravity1()
clear;
format long eng;
load('solar_system_data.mat');
StartTime = 0;
TimeStep = 24 * 3600 * 10;
EndTime = 24 * 3600 * 100;
TVec = StartTime:TimeStep:EndTime;
TimeStepMin = StartTime:2:TimeStep;
%Column Vectors for initial conditions
SunVec = [xposition(1), yposition(1), vx(1), vy(1),mass(1),1];
MercuryVec = [xposition(2), yposition(2), vx(2), vy(2),mass(2),2];
VenusVec = [xposition(3), yposition(3), vx(3), vy(3),mass(3),3];
EarthVec = [xposition(4), yposition(4),vx(4), vy(4),mass(4),4];
MoonVec = [xposition(10), yposition(10), vx(10), vy(10),mass(10),10];
MarsVec = [xposition(5), yposition(5), vx(5), vy(5),mass(5),5];
JupiterVec = [xposition(6), yposition(6), vx(6), vy(6),mass(6),6];
SaturnVec = [xposition(7), yposition(7), vx(7), vy(7),mass(7),7];
UranusVec = [xposition(8), yposition(8), vx(8), vy(8),mass(8),8];
NeptuneVec = [xposition(9), yposition(9), vx(9), vy(9),mass(9),9];
PlanetVec=[SunVec(1),SunVec(2),SunVec(3),SunVec(4),SunVec(5),SunVec(6);MercuryVec(1), MercuryVec(2), MercuryVec(3), MercuryVec(4),MercuryVec(5),MercuryVec(6);VenusVec(1), VenusVec(2), VenusVec(3), VenusVec(4),VenusVec(5),VenusVec(6);EarthVec(1), EarthVec(2), EarthVec(3), EarthVec(4),EarthVec(5),EarthVec(6);MoonVec(1),MoonVec(2),MoonVec(3),MoonVec(4),MoonVec(5),MoonVec(6);MarsVec(1), MarsVec(2), MarsVec(3), MarsVec(4),MarsVec(5),MarsVec(6);JupiterVec(1), JupiterVec(2), JupiterVec(3), JupiterVec(4),JupiterVec(5),JupiterVec(6);SaturnVec(1), SaturnVec(2), SaturnVec(3), SaturnVec(4),SaturnVec(5),SaturnVec(6);UranusVec(1), UranusVec(2),UranusVec(3), UranusVec(4),UranusVec(5),UranusVec(6);NeptuneVec(1), NeptuneVec(2), NeptuneVec(3), NeptuneVec(4),NeptuneVec(5),NeptuneVec(6)];
n=0;
while n<EndTime;
%Built in solver
[TimeVec, SunMat] = ode45(@GravityDE, TimeStepMin, SunVec);
[TimeVec, MercuryMat] = ode45(@GravityDE, TimeStepMin, MercuryVec);
[TimeVec, VenusMat] = ode45(@GravityDE, TimeStepMin, VenusVec);
[TimeVec, EarthMat] = ode45(@GravityDE, TimeStepMin, EarthVec);
[TimeVec, MoonMat] = ode45(@GravityDE, TimeStepMin, MoonVec);
[TimeVec, MarsMat] = ode45(@GravityDE, TimeStepMin, MarsVec);
[TimeVec, JupiterMat] = ode45(@GravityDE, TimeStepMin, JupiterVec);
[TimeVec, SaturnMat] = ode45(@GravityDE, TimeStepMin, SaturnVec);
[TimeVec, UranusMat] = ode45(@GravityDE, TimeStepMin, UranusVec);
[TimeVec, NeptuneMat] = ode45(@GravityDE, TimeStepMin, NeptuneVec);
SunXVec = SunMat (end,1);
SunYVec = SunMat (end,2);
SunVXVec = SunMat(end,3);
SunVYVec = SunMat(end,4);
MercuryXVec = MercuryMat (end,1);
MercuryYVec = MercuryMat (end,2);
MercuryVXVec = MercuryMat(end,3);
MercuryVYVec = MercuryMat(end,4);
VenusXVec = VenusMat (end,1);
VenusYVec = VenusMat (end,2);
VenusVXVec = VenusMat(end,3);
VenusVYVec = VenusMat(end,4);
EarthXVec = EarthMat (end,1);
EarthYVec = EarthMat (end,2);
EarthVXVec = EarthMat(end,3);
EarthVYVec = EarthMat(end,4);
MoonXVec = MoonMat (end,1);
MoonYVec = MoonMat (end,2);
MoonVXVec = MoonMat(end,3);
MoonVYVec =MoonMat(end,4);
MarsXVec = MarsMat (end,1);
MarsYVec = MarsMat (end,2);
MarsVXVec = MarsMat(end,3);
MarsVYVec = MarsMat(end,4);
JupiterXVec = JupiterMat (end,1);
JupiterYVec = JupiterMat (end,2);
JupiterVXVec = JupiterMat(end,3);
JupiterVYVec =JupiterMat(end,4);
SaturnXVec = SaturnMat (end,1);
SaturnYVec = SaturnMat (end,2);
SaturnVXVec = SaturnMat(end,3);
SaturnVYVec =SaturnMat(end,4);
UranusXVec = UranusMat (end,1);
UranusYVec = UranusMat (end,2);
UranusVXVec = UranusMat(end,3);
UranusVYVec =UranusMat(end,4);
NeptuneXVec = NeptuneMat (end,1);
NeptuneYVec = NeptuneMat (end,2);
NeptuneVXVec = NeptuneMat(end,3);
NeptuneVYVec =NeptuneMat(end,4);
SunVec=[SunXVec,SunYVec,SunVXVec,SunVYVec,mass(1),1];
MercuryVec = [MercuryXVec, MercuryYVec, MercuryVXVec, MercuryVYVec,mass(2),2];
VenusVec = [VenusXVec, VenusYVec, VenusVXVec, VenusVYVec,mass(3),3];
EarthVec = [EarthXVec, EarthYVec, EarthVXVec, EarthVYVec,mass(4),4];
MoonVec = [MoonXVec,MoonYVec,MoonVXVec,MoonVYVec,mass(10),10];
MarsVec = [MarsXVec, MarsYVec, MarsVXVec, MarsVYVec,mass(5),5];
JupiterVec = [JupiterXVec, JupiterYVec, JupiterVXVec, JupiterVYVec,mass(6),6];
SaturnVec = [SaturnXVec, SaturnYVec, SaturnVXVec, SaturnVYVec,mass(7),7];
UranusVec = [UranusXVec, UranusYVec,UranusVXVec, UranusVYVec,mass(8),8];
NeptuneVec = [NeptuneXVec, NeptuneYVec, NeptuneVXVec, NeptuneVYVec,mass(9),9];
PlanetVec=[SunVec(1),SunVec(2),SunVec(3),SunVec(4),SunVec(5),SunVec(6);MercuryVec(1), MercuryVec(2), MercuryVec(3), MercuryVec(4),MercuryVec(5),MercuryVec(6);VenusVec(1), VenusVec(2), VenusVec(3), VenusVec(4),VenusVec(5),VenusVec(6);EarthVec(1), EarthVec(2), EarthVec(3), EarthVec(4),EarthVec(5),EarthVec(6);MoonVec(1),MoonVec(2),MoonVec(3),MoonVec(4),MoonVec(5),MoonVec(6);MarsVec(1), MarsVec(2), MarsVec(3), MarsVec(4),MarsVec(5),MarsVec(6);JupiterVec(1), JupiterVec(2), JupiterVec(3), JupiterVec(4),JupiterVec(5),JupiterVec(6);SaturnVec(1), SaturnVec(2), SaturnVec(3), SaturnVec(4),SaturnVec(5),SaturnVec(6);UranusVec(1), UranusVec(2),UranusVec(3), UranusVec(4),UranusVec(15),UranusVec(6);NeptuneVec(1), NeptuneVec(2), NeptuneVec(3), NeptuneVec(4),NeptuneVec(5),NeptuneVec(6)];
plot (SunXVec,SunYVec,'.','Color','yellow');
hold on;
plot (MercuryXVec,MercuryYVec,'.','Color','green');
hold on;
plot (VenusXVec,VenusYVec,'.','Color','blue');
hold on;
plot (EarthXVec,EarthYVec, '.','Color', 'red');
hold on;
plot (MoonXVec,MoonYVec, '.','Color','black');
hold on;
plot (MarsXVec,MarsYVec, '.','Color','black');
hold on;
plot (JupiterXVec,JupiterYVec,'.','Color','green');
hold on;
plot (SaturnXVec,SaturnYVec, '.','Color','blue');
hold on;
plot (UranusXVec,UranusYVec, '.','Color','red');
hold on;
plot (NeptuneXVec,NeptuneYVec, '.','Color','blue');
hold on;
n=n+TimeStep;
end
function dYVec = GravityDE (TimeStep, YVec,PlanetVec)
load('solar_system_data.mat');
GravConst = 6.67259e-11;
Xi = YVec(1);
Yi = YVec(2);
VXi = YVec(3);
VYi = YVec(4);
Massi=YVec(5);
BodyName=YVec(6);
AccXtotal=0;
AccYtotal=0;
j=1;
while j<=10
Massj=PlanetVec(j,5);
Yj=PlanetVec(j,2);
Xj=PlanetVec(j,1);
RangeSq = (Xi-Xj).^2 + (Yi-Yj).^2;
if RangeSq==0
AccMag=0;
Theta = atan2(Yi-Yj,Xi-Xj);
AccX = -AccMag .* cos (Theta);
AccY = -AccMag .* sin (Theta);
j=j+1;
AccXtotal=AccXtotal+AccX;
AccYtotal=AccYtotal+AccY;
else
Theta = atan2(Yi-Yj,Xi-Xj);
AccMag = (GravConst .* Massj ./ RangeSq);
AccX = -AccMag .* cos (Theta);
AccY = -AccMag .* sin (Theta);
j=j+1;
AccXtotal=AccXtotal+AccX;
AccYtotal=AccYtotal+AccY;
VXi=VXi+AccXtotal.*TimeStep;
VYi=VYi+AccYtotal.*TimeStep;
end
dYVec = [VXi; VYi; AccXtotal; AccYtotal;Massi;BodyName];
end
```

Thanks!!

`ode45`

only considers 1 planet...which renders those integrations into a complicated way to discover Keplerian motion :) – Rody Oldenhuis Nov 15 '12 at 5:19Gto getGMis mortal sin.Gis theleastprecisely known physical constant! What you measure when you do orbital analysis (that's how all the masses of all the planets are measured) is the productGM(which is usually calledμ, the standard gravitational parameter). The accuracy with which theμ's of all the planets are known, are orders of magnitude better than their masses (which are simply calcualated asμ/G). – Rody Oldenhuis Nov 15 '12 at 5:34