Let u(x) and v(x) be differentiable functions such that
`(u(x))/(v(x))=7.if(u'(x))/(v'(x))=pand((u(x))/(v(x)))'=q," then "(p+q)/(p-q)` has the value equal to

If y=(u)/(v) , where u and v are functions of x, show that v^(3)(d^(2)y)/(dx^(2))=|{:(u,v,0),(u',v',v),(u'',v'',2v'):}| .

If u, v and w are functions of x, then show that (d)/(dx) (u.v.w) = (du)/(dx) v.w + u.(dv)/(dx).w + u.v.(dw)/(dx) in two ways- first by repeated application of product rule, second by logarithmic differentiation. Using product rule

Let the derivative of f(x) be defined as D^(**)f(x)=lim_(hrarr0)(f^(2)(x+h)-f^(2)(x))/(h), where f^(2)(x)={f(x)}^(2) . If u=f(x),v=g(x) , then the value of D^(**)(u.v) is

If p(q-r)x^2+q(r-p)x+r(p-q)=0 has equal roots, then;

The probability function of the binomial distribution is P(x)= ((6), (x))p^(x)q^(6-x), x= 0, 1, 2, ....., 6. If 2P(2) = 3P(3) then value of q is ……….

The value of lim_(xto0)(p^(x)-q^(x))/(r^(x)-s^(x)) is

A particle located in one dimensional potential field has potential energy function U(x)=(a)/(x^(2))-(b)/(x^(3)) , where a and b are positive constants. The position of equilibrium corresponds to x equal to

Integration of some particular functions : int (sin 2x)/(p cos^(2) x+q sin^(2)x) dx=.....+c