I am still convinced that transform matrices will be much better approach for you

As mentioned in previous question **Euler angles** are not the best for your purpose and only mess thing up for you but anyway what about this:

```
P0=(0,0,0)
P1=(1,0,0) // or (0,0,1) y=0 !!!
A0=r2_localtoglobal(P0)
A1=r2_localtoglobal(P1)
B0=r2r1_localtoglobal(P0)
B1=r2r1_localtoglobal(P1)
A=A1-A0 // local r2 X axis direction in GCS (without r1)
B=B1-B0 // local r2r1 X axis direction in GCS (with r1)
angle=-acos((A.B)/(|A|.|B|)) // angle between A,B (but inverted because you wanted local angle)
```

I assume `r1`

is ship and `r2`

is radar

**[Edit1]** after read of your edit from linked question is finally clear what you want

```
P0=(0,0,0)
P1=(1,0,0) // or (0,0,1) y=0 !!!
A0=r1_globaltolocal(P0)
A1=r1_globaltolocal(P1)
A=A1-A0
angle=atanxy(A.x,A.z)
```

- where
`r1`

is your ship transformation
- radar transformation is irelevant to background image
`atanxy`

is `atan2(y,x) = atan(y/x)`

but with sign decomposition so it works on whole `< 0,2PI >`

interval

**atan2,atanxy:**

```
const double pi=M_PI;
const double pi2=2.0*M_PI;
double atanxy(double x,double y) // atan2 return < 0 , 2.0*M_PI >
{
int sx,sy;
double a;
const double _zero=1.0e-30;
sx=0; if (x<-_zero) sx=-1; if (x>+_zero) sx=+1;
sy=0; if (y<-_zero) sy=-1; if (y>+_zero) sy=+1;
if ((sy==0)&&(sx==0)) return 0;
if ((sx==0)&&(sy> 0)) return 0.5*pi;
if ((sx==0)&&(sy< 0)) return 1.5*pi;
if ((sy==0)&&(sx> 0)) return 0;
if ((sy==0)&&(sx< 0)) return pi;
a=y/x; if (a<0) a=-a;
a=atan(a);
if ((x>0)&&(y>0)) a=a;
if ((x<0)&&(y>0)) a=pi-a;
if ((x<0)&&(y<0)) a=pi+a;
if ((x>0)&&(y<0)) a=pi2-a;
return a;
}
```

`r3 = r2.r1`

then`T1 = r1.T0`

and`T2 = r2.T1`

then`T2 = r2.r1.T0`

which is`T2 = r3.T0`

– Felix Castor Feb 10 '14 at 16:55