\[
\frac{ 1 }{ \Delta t }\ \frac{ v'_x - v_x }{ v } \\
\ \\
= \frac{ 1 }{ \Delta t }\ ( - ( cos(\theta) cos(\Omega \Delta t) + sin(\theta) sin(\Omega \Delta t) ) - ( - cos( \theta ) ) ) \\
\ \\
= \frac{ 1 }{ \Delta t }\ ( cos(\theta)\ ( 1 - cos(\Omega \Delta t) ) - sin(\theta)\ sin(\Omega \Delta t) )\\
\ \\
= cos(\theta)\ \frac{ 1 - cos(\Omega \Delta t ) }{ \Delta t }\ - sin(\theta)\ \frac{ sin(\Omega \Delta t) ) }{ \Delta t } \\
\ \\
= cos(\theta)\ ( \Omega^2\ \Delta t )\ \frac{ 1 - cos(\Omega \Delta t ) }{ ( \Omega\ \Delta t )^2 }\
- sin(\theta)\ \Omega\ \frac{ sin(\Omega \Delta t) ) }{ \Omega\ \Delta t } \\
\ \\ \ \\
\longrightarrow \ 0 - sin(\theta)\ \Omega\ \ \ ( \Delta t \rightarrow 0 ) \\
\]
\[
\frac{ 1 }{ \Delta t }\ \frac{ v'_y - v_y }{ v } \\
\ \\
= \frac{ 1 }{ \Delta t }\ ( ( sin(\theta) cos(\Omega \Delta t) - cos(\theta) sin(\Omega \Delta t) ) - sin( \theta ) ) \\
\ \\
= \frac{ 1 }{ \Delta t }\ ( - sin(\theta)\ ( 1 - cos(\Omega \Delta t) ) - cos(\theta)\ sin(\Omega \Delta t) )\\
\ \\
= - sin(\theta)\ \frac{ 1 - cos(\Omega \Delta t ) }{ \Delta t }\ - cos(\theta)\ \frac{ sin(\Omega \Delta t) ) }{ \Delta t } \\
\ \\
= - sin(\theta)\ ( \Omega^2\ \Delta t )\ \frac{ 1 - cos(\Omega \Delta t ) }{ ( \Omega\ \Delta t )^2 }\ -
- cos(\theta)\ \Omega\ \frac{ sin(\Omega \Delta t) ) }{ \Omega\ \Delta t } \\
\ \\ \ \\
\longrightarrow \ 0 - cos(\theta)\ \Omega\ \ \ ( \Delta t \rightarrow 0 ) \\
\]
よって,
\[
\frac{ {\bf v'} - {\bf v} }{\Delta t}
\longrightarrow ( - v\ \Omega\ sin(\theta),\ - v\ \Omega\ cos(\theta) ) \ \ \ ( \Delta t \rightarrow 0 )
\]
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