Answer:
[tex]\Delta d =\frac{y-x}{y}*d_{Hs}\[/tex]
Step-by-step explanation:
Fist the velocity of high-speed train will be given by:
[tex]V_{Hs} =\frac{z}{x}[/tex]
And the velocity of the regular will be given by:
[tex]V_{R} =\frac{z}{y}[/tex]
The position equations of each movement will be given by:
[tex]d_{Hs} =\frac{z}{x} t[/tex]
[tex]d_{R} =z-\frac{z}{y} t[/tex]
We can get the encounter point isolating t in the first equation and reepalcing it in the second one:
First isolating:
[tex]d_{Hs}\frac{x}{z} = t[/tex]
Second reeplacing t:
[tex]d_{R} =z-\frac{z}{y}*d_{Hs}\frac{x}{z}[/tex]
[tex]d_{R}=z-\frac{x}{y}*d_{Hs}\[/tex]
In the moment of the encounter the high-speed train have gone round [tex]d_{Hs}\[/tex] and the regular one [tex]\frac{x}{y}*d_{Hs}\[/tex]
Then the difference between the distance traveled the high-speed train and the regular one is:
[tex]\Delta d =d_{Hs}-\frac{x}{y}*d_{Hs}\[/tex]
[tex]\Delta d =\frac{y-x}{y}*d_{Hs}\[/tex]
