Two identical coherent sources of wavelength `lambda` are placed at `(100 lambda, 0)` and `(-50 lambda, 0)` along x-axis. The number of maxima and minima detected are ,respectively [include origin and `(5 lambda, 0)]`

Two coherent sources A & B emitting light of wavelength lambda are placed at position (-D,0) and (-D,3lambda) respectively Here D gt gt lambda The number of minima on y-axis and maxima on x-axis respectively are

Two coherent sources emit light of wavelength lambda . Separation between them, d = 4 lambda . If a detector moves along the y-axis, what is the maximum number of minima observed?

Two coherent sources emit light of wavelength lambda . Separation between them, d = 4 lambda . If a detector moves along the y-axis, what is the maximum number of minima observed?

Two coherent light sources, each of wavelength lambda , are separated by a distance 3 lambda , The maximum number of minima formed on line AB, which funs from -oo to +oo , is

Two coherent light sources, each of wavelength lambda , are separated by a distance 3 lambda , The maximum number of minima formed on line AB, which funs from -oo to +oo , is

If , lambda_(1) and lambda_(2) are the wavelength of the numbers of the Lyman and Paschen seri respectively. Then lambda_(1):lambda_(2)= .....

Two coherent sources emit light of wavelength lambda . Separation between them, d = 4 lambda . If a detector moves along the y-axis, what is the maximum number of minima observed? If the detector moves along 'x-axis beginning from S_(2) , the maximum number of minima observed is

The two coherent sources of monochromatic light of wavelength lambda are located at a separation lambda . The two sources are placed on a horizontal line and screen is placed perpendicular to the line joining the sources. Find position of the farthest minima from the centre of the sources.