I am confused by a question. I thought "right handed set" only applied to sets of three vectors. However I have been given 2 vectors and asked "check whether they are perpendicular to each other and if they form a right handed set. If they don't form a right handed set, the second vector must be...
So would I do ##\Delta T = \Delta \frac{\lambda}{\lambda f}=T\sqrt{(\frac{\Delta \lambda}{\lambda})^2+(\frac{\Delta \lambda}{\lambda})^2+(\frac{\Delta f}{f})^2}##? Somehow this doesn't seem right.
My textbook derives the condition for bright and dark fringes on an air wedge by assuming that the reflected and refracted rays have a path difference of pi. Hence the conditions for bright and dark fringes end up being the opposite of what is expected.
However I did not really understand the...
Also is there an
I didn't use the wavelength uncertainty in my first calculation. I just wrote T=1/f and used propagation formula for division, with 1 and f as the "variables". I dropped the first term under square root because I thought ##\frac{\Delta 1 }{1} =0##.
Calculate the speed and uncertainty in the speed for a wave with wavelength ##50\pm 3\mu s## and frequency ##30\pm 1kHz##. Also calculate the period and uncertainty in the period.
I am not sure about my answer to the second part. I used propagation of errors to get ##\Delta...
Thanks for your reply. Unfortunately this also gives a wrong answer (according to book) of D=1.01m.
There is a similar question which I am also getting the wrong answer for so I don't think it is a mistake in the book, however I can't see what I am doing wrong.
In Young's double split experiment, a narrow beam of light of wavelength ##589nm## passes through two slits to form an interference pattern on a screen which is a perpendicular distance of ##D## metres away from the slits. The slit separation is ##0.2mm## and the second bright fringe is ##6mm##...
An air wedge is illuminated with light and an interference pattern is produced. What will happen to the interference pattern when the air wedge is filled with water?
The answer given at the back of the book is that the fringe spacing of the interference pattern will increase, however my...
Thank you I will use LaTeX next time.
It is given as 330 in the formula booklet so I don't think so.
Would it be ok to just post the question rather than asking for confirmation of my answer? Or is there some other way it should be done?
Is my solution correct?
I used v=lambda*f, i.e. f=v/lambda to get the frequency for each wave. Then I calculated the average of the frequencies to get 258Hz and found the beat frequency by doing f1-f2 to get 4Hz. I then said that this means the observer will hear a tone of frequency 258Hz which...
I wasn't sure about my solution for part c. I said "same distance as for traveling wave ie \lambda/2=0.06m".
Also how do you enter LaTeX on this forum?