You want an initial condition I(t=0) that belongs to the periodical steady state solution, in other words the decaying transient solution should have zero magnitude. The waveform in post #7 shows what it is.
So you are backing up my theory shown in post #11. We want the particular case when R=0 to behave in the steady state like a more general case RL would behave. (I have explained that regarding the sinusoidal steady state)
The RL general case in the steady state has 0 DC current, which means we must set the initial condition (i(0)) for the particular case when R=0 in such a way that leads to 0 DC current.
For the case when R=0 (pure L), i(D*T)=Δi + i(0)=V/L *D*T +i(0) which is also equal to Idc+Δi/2 (because is a triangular wave). Now, Idc=0, then i(0)=Δi/2-Δi= -Δi/2 = Initial condition we must set.
That is what I was looking for, the reason behind how is the initial condition (i(0)) set.
Since you are backing me up, I will take this as a founded reason :-D in order to select the initial condition.
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For the sinusoidal steady state.
Since i(t)=-V/ωL *cos(ωt) + IC+V/ωL = -V/ωL *cos(ωt) + DC value
To back up the above reasoning, we want it to behave the same in the steady state as a RL would, which means, we must set DC value=0, which leads to set IC+V/ωL=0, which leads to IC=i(0)=-V/ωL
i(0)=-V/ωL is the
nontrivial,
unfounded explanation Physics books give when they plot the current waveform of a pure L circuit when excited with a sinusoidal voltage source. i(t)=-V/ωL *cos(ωt)=V/ωL *sin(ωt-Π/2) which is what we all know from the phasorial analysis.