If the straight lines `x=-1+s ,y=3-lambdas ,z=1+lambdasa n dx=t/2,y=1+t ,z=2-t ,` with parameters `s` and `t ,` respectively, are coplanar, then find `lambdadot`

If the lines (x-2)/(1) = (y-3)/(1) = (4-z)/(lambda) and (x-1)/(lambda) = (y-4)/(2) = (z-5)/(1) are intersect each other than lambda = ..........

The equation of two straight lines are (x-1)/2=(y+3)/1=(z-2)/(-3)a n d(x-2)/1=(y-1)/(-3)=(z+3)/2dot Statement 1: the given lines are coplanar. Statement 2: The equations 2x_1-y_1=1,x_1+3y_1=4a n d3x_1+2y_1=5 are consistent.

If the straight lines (x-1)/(2)=(y+1)/(k)=(z)/(2) and (z+1)/(5)=(y+1)/(2)=(z)/(k) are coplanar, then the plane(s) containing these two lines is/are

Consider radioactive decay of A to B with which further decays either to X or Y , lambda_(1), lambda_(2) and lambda_(3) are decay constant for A to B decay, B to X decay and Bto Y decay respectively. At t=0 , the number of nuclei of A,B,X and Y are N_(0), N_(0) zero and zero respectively. N_(1),N_(2),N_(3) and N_(4) are the number of nuclei of A,B,X and Y at any instant t . The net rate of accumulation of B at any instant is

A particle moves in such a manner that x=At, y=Bt^(3)-2t, z=ct^(2)-4t , where x, y and z are measured in meters and t is measured in seconds, and A, B and C are unknown constants. Give that the velocity of the particle at t=2s is vec(v)=((dvec(r))/(dt))=3hat(i)+22hat(j) m//s , determine the velocity of the particle at t=4s .

A car moves along a straight line whose equation of motion is given by s=12t+3t^(2)-2t^(3) where s is in metres and t is in seconds. The velocity of the car at start will be :-

x=a sin t and y= a (cos t + log "tan"(t)/(2)) then find (d^(2)y)/(dx^(2)) .

Find the locus of a point whose coordinate are given by x = t+t^(2), y = 2t+1 , where t is variable.

The position of a particle is given by x=7+ 3t^(3) m and y=13+5t-9t^(2)m , where x and y are the position coordinates, and t is the time in s. Find the speed (magnitude of the velocity) when the x component of the acceleration is 36 m//s^(2) .