- #1
thenewbosco
- 187
- 0
There are two parts to this but i solved the first part:
in part a) i was to show, for an electomagnetic wave reflected back to its source from a mirror approaching at speed v, that the reflected wave had frequency [tex] f=f_{source}\frac{c+v}{c-v}[/tex] where fsource is the source frequency and c is the speed of light.
now i am asked: when v is much less than c, the beat frequency is much smaller than the transmitted frequency. In this case use the approximation [tex] f + f_{source}\approx 2f_{source}[/tex] and show that the beat frequency can be written:
[tex]f_{beat}=\frac{2v}{\lambda}[/tex]
i don't know how to go about this. I was thinking to solve for fsource and put it into the equation from part a. but this doesn't work...any help
in part a) i was to show, for an electomagnetic wave reflected back to its source from a mirror approaching at speed v, that the reflected wave had frequency [tex] f=f_{source}\frac{c+v}{c-v}[/tex] where fsource is the source frequency and c is the speed of light.
now i am asked: when v is much less than c, the beat frequency is much smaller than the transmitted frequency. In this case use the approximation [tex] f + f_{source}\approx 2f_{source}[/tex] and show that the beat frequency can be written:
[tex]f_{beat}=\frac{2v}{\lambda}[/tex]
i don't know how to go about this. I was thinking to solve for fsource and put it into the equation from part a. but this doesn't work...any help