How to find transverse component of star's velocity given its proper motion and distance from observation point?

If $mu$ is the proper motion of a star in arcseconds per year, and $d$ is the star’s distance from us, then the transverse speed, $v_t$ will be
$$v_t=dsinmu$$
For small motions (assumed for this question) $sinmuapprox mu$

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Barnard’s star has a measured parallax of $0.55, rm{arcsec}$. Barnard’s star also has a proper motion of $10.3$ arcsec per year. What component of the star’s velocity relative to the Sun can be deduced from the proper motion? Calculate this component, in $rm{kms^{−1}}$.

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This is the way I thought the transverse speed should be calculated:

Firstly, $d$, can be determined through the trigonometric parallax, $p$:
$$d(rm{pc})=frac{1}{p(rm{arcsec})}$$

For a parallax of $0.55, rm{arcsec}$

$$d=frac{1}{0.55}approx 1.8 {rm, pc}$$
Using the fact that $1,rm{pc}=3.1times 10^{16},rm{m}$ & $1, rm{yr}=3times 10^7,rm{s}$
$$begin{align}v_t&=dmu &=1.8 ,rm{pc}times frac{3.1times 10^{16}rm{m}}{pc}timesfrac{10.3 ,color{green}{rm{arcsec}}}{3times 10^7,rm{s}}&=frac{1.8times 3.1times 10^{16}times 10.3,rm{m}}{3times 10^7,rm{s}}&approx 1.92times 10^{10},rm{m,s^{-1}}&=1920times 10^7 ,rm{km,s^{-1}} end{align}$$

The part marked green I have omitted since it is dimensionless.

Before asking this I searched for an answer and found this similar question which also omitted a dimensionless unit (which was radians in their case).

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The correct answer is

At the distance of Barnard’s star ($1.8 ,rm{pc}$), $bbox[yellow]{{text{an angle of} , 10.3 , rm{arcsec}, text{corresponds to}, 1.8 times 10.3 , rm{AU}}}$, or $1.8 times 10.3 times 1.5 × 10^{11},rm{m}$. This is the distance covered in $1$ year, or $sim 3 times 10^7,rm{s}$, yielding a velocity of about $90 , rm{km, s^{−1}}$.

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I have highlighted in yellow the part I do not understand in the solution. Why does $bbox[yellow,5px,border:2px solid red]{{text{an angle of} , 10.3 , rm{arcsec}, text{correspond to}, 1.8 times 10.3 , rm{AU}}},$?

Specifically, I don’t understand why the $rm {AU}$ comes into this (I thought the distances were in $rm{pc}$, not $rm{AU}$).