How to derive the bank angle of an aircraft from its roll angle and pitch angle?

Question

From Young (2017) (https://onlinelibrary.wiley.com/doi/book/10.1002/9781118534786) it is stated that we can define the bank angle ($Phi$) of an aircraft as the angle between its Y body axis and the horizontal plane. He then states the following equivalence:
$sin(Phi)=sin(phi)cos(theta)$
where $theta$ is the pitch angle of the aircraft and $phi$ is its roll angle. I want to derive this equivalence and this is my attempt so far which yields an alternative expression:
I define a global axis system $E=(O,X_e,Y_e,Z_e)$ where $O=begin{bmatrix} 0  0  0  end{bmatrix}$ is the origin of the system, and $X_e=begin{bmatrix} 1  0  0  end{bmatrix}$, $Y_e=begin{bmatrix} 0  1  0  end{bmatrix}$ and $Z_e=begin{bmatrix} 0  0  1  end{bmatrix}$ are orthonormal unit vectors which define North, East and 'down' respectively.
I also define an aircraft body axis system, $B=(O,X_b,Y_b,Z_b)$, whose starting orientation and position is coincident with $E$.
I first rotate $B$ about the $Y_b$ axis an angle $theta$, the pitch rotation, and then I rotate this rotated body axis system about its new $Xb$ axis an angle $phi$, the roll rotation. The relevant rotation matrices are:
$R_Y(theta)$=begin{bmatrix} cos(theta) & 0 & sin(theta)  0 & 1 & 0  -sin(theta) & 0 & cos(theta) end{bmatrix}
$R_X(phi)$=begin{bmatrix} 1 & 0 & 0  0 & cos(phi) & -sin(phi)  0 & sin(phi) & cos(phi) end{bmatrix}
which when applied in the correct order to specify the rotations outlined in the text above yields the composite matrix:
$R_Y(theta)R_X(phi)=R=$begin{bmatrix} cos(theta) & sin(theta)sin(phi) & sin(theta)cos(phi)  0 & cos(phi) & -sin(phi)  -sin(theta) & cos(theta)sin(phi) & cos(theta)cos(phi) end{bmatrix}
I then have $B2=RB=R$ which is the body axis system after the rotations. $Y_{B2}= begin{bmatrix} sin(theta)sin(phi)  cos(phi)  cos(theta)sin(phi) end{bmatrix}$, the y axis of B2, and its projection onto the horizontal plane is $Y_{pB2}= begin{bmatrix} sin(theta)sin(phi)  cos(phi)  0 end{bmatrix}$. I can then say that the cosine of the angle between them, the bank angle $Phi$, is the normalised dot product of the two vectors:
begin{align}
cos(Phi)=frac{Y_{B2}cdot Y_{pB2}}{|Y_{B2}||Y_{pB2}|}
end{align}
Doing the computation I am left with:
begin{align}
cos(Phi)=sin(theta)sin(phi) + cos(phi)
end{align}
Whereas I want:
begin{align}
sin(Phi)=sin(phi)cos(theta)
end{align}
Any advice on where I have gone wrong would be much appreciated.

Eli · Accepted Answer

$$vec{y'}=left[ begin {array}{c} sin left( theta right) sin left( phi
 right) cos left( phi right) 
 cos left( theta right) sin left( phi
 right) end {array} right] 
$$
$Rightarrow$
$$tan(Phi)=frac{sin(Phi)}{cos(Phi)}=frac{vec{y'}_x}{vec{y'}_y}=frac{sin(theta),sin(phi)}{cos(phi)}$$
thus:
$$sin(Phi)=sin(theta),sin(phi)$$
but this angle is not the angle between y‘ and the plane xy

How to derive the bank angle of an aircraft from its roll angle and pitch angle?

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