Have a query? Ask a Tutor!!

Access to best educators and exclusive paper discussions

Offsite Campus Turito Championship

Can’t find what you’re looking for?

Our tutors are from top schools around the world, and they are waiting for you 24/7, anytime, anywhere.

Homework- One to One Solutions
Understand concepts to solve better
Get your doubts solved instantly

Maths-

General

Easy

Question

The order of differential equation is $open parentheses fraction numerator d squared y over denominator d x squared end fraction close parentheses cubed equals open parentheses 1 plus fraction numerator d y over denominator d x end fraction close parentheses to the power of 1 divided by 2 end exponent$

2
3
$\frac{1}{2}$
6

hint Hint:

In this question we have to find the order of the given differential equation. For this we will first arrange the equation in a proper way. Now we know that the order of a differential equation is the order of the highest order derivative involved in the differential equation.

The correct answer is: 2

$open parentheses fraction numerator d squared y over denominator d x squared end fraction close parentheses cubed equals open parentheses 1 plus fraction numerator d y over denominator d x end fraction close parentheses to the power of 1 divided by 2 end exponent rightwards double arrow open parentheses fraction numerator d squared y over denominator d x squared end fraction close parentheses to the power of 6 equals 1 plus fraction numerator d y over denominator d x end fraction rightwards double arrow open parentheses fraction numerator d squared y over denominator d x squared end fraction close parentheses to the power of 6 minus fraction numerator d y over denominator d x end fraction equals 1$
order = 2

Related Questions to study

Two condensers, one of capacity $C$ and the other of capacity $fraction numerator C over denominator 2 end fraction$ , are connected to a $V$ volt battery , as shown. The work done in charging fully both the condensers is

Two condensers, one of capacity $C$ and the other of capacity $fraction numerator C over denominator 2 end fraction$ , are connected to a $V$ volt battery , as shown. The work done in charging fully both the condensers is

physics-General

A cubical block of side ‘L’ rests on a rough horizontal surface with coefficient of friction ‘m’ A horizontal force F is applied on the block as shown. If the coefficient of friction is sufficiently high so that the block does not slide before toppling, the minimum force required to topple the block is

A cubical block of side ‘L’ rests on a rough horizontal surface with coefficient of friction ‘m’ A horizontal force F is applied on the block as shown. If the coefficient of friction is sufficiently high so that the block does not slide before toppling, the minimum force required to topple the block is

physics-General

If the time period of a pendulum is 1 sec, then what is the length of the pendulum at point of intersection of l-T and $l minus T to the power of 2 end exponent$ graph

If the time period of a pendulum is 1 sec, then what is the length of the pendulum at point of intersection of l-T and $l minus T to the power of 2 end exponent$ graph

physics-General

parallel

Order and degree of differential equation $fraction numerator d squared y over denominator d x squared end fraction equals open square brackets y plus open parentheses fraction numerator d y over denominator d x end fraction close parentheses squared close square brackets to the power of 1 divided by 4 end exponent$ are

Order and degree of differential equation $fraction numerator d squared y over denominator d x squared end fraction equals open square brackets y plus open parentheses fraction numerator d y over denominator d x end fraction close parentheses squared close square brackets to the power of 1 divided by 4 end exponent$ are

The solution of $x squared fraction numerator d y over denominator d x end fraction minus x y equals 1 plus cos space y over x$ is

The solution of $x squared fraction numerator d y over denominator d x end fraction minus x y equals 1 plus cos space y over x$ is

For the given figure, calculate zero correction.

For the given figure, calculate zero correction.

physics-General

parallel

Three capacitors $C subscript 1 end subscript comma C subscript 2 end subscript a n d C subscript 3 end subscript$ are connected as shown in the figure to a battery of $V$ volt. If the capacitor $C subscript 3 end subscript$ breaks down electrically the change in total charge on the combination of capacitors is

Three capacitors $C subscript 1 end subscript comma C subscript 2 end subscript a n d C subscript 3 end subscript$ are connected as shown in the figure to a battery of $V$ volt. If the capacitor $C subscript 3 end subscript$ breaks down electrically the change in total charge on the combination of capacitors is

physics-General

The charge deposited on $4 mu F$ capacitor the circuit is

The charge deposited on $4 mu F$ capacitor the circuit is

physics-General

If $y equals e to the power of negative x end exponent left parenthesis A cos space x plus B sin space x right parenthesis$ then y satisfies

If $y equals e to the power of negative x end exponent left parenthesis A cos space x plus B sin space x right parenthesis$ then y satisfies

parallel

In the figure, a proton moves a distance d in a uniform electric field E as shown in the figure. Does the electric field do a positive or negative work on the proton? Does the electric potential energy of the proton increase or decrease?

In the figure, a proton moves a distance d in a uniform electric field E as shown in the figure. Does the electric field do a positive or negative work on the proton? Does the electric potential energy of the proton increase or decrease?

physics-General

Solution of $fraction numerator d y over denominator d x end fraction equals e to the power of y plus x end exponent plus e to the power of y minus x end exponent$ is

Solution of $fraction numerator d y over denominator d x end fraction equals e to the power of y plus x end exponent plus e to the power of y minus x end exponent$ is

Two charges $q subscript 1 end subscript$ and $q subscript 2 end subscript$ are placed 30 cm apart, as shown in the figure. A third charge $q subscript 3 end subscript$ is moved along the arc of a circle of radius 40 cm from C to D. The change in the potential energy of the system is $fraction numerator q subscript 3 end subscript over denominator 4 pi epsilon subscript 0 end subscript end fraction k comma$ where k is

Two charges $q subscript 1 end subscript$ and $q subscript 2 end subscript$ are placed 30 cm apart, as shown in the figure. A third charge $q subscript 3 end subscript$ is moved along the arc of a circle of radius 40 cm from C to D. The change in the potential energy of the system is $fraction numerator q subscript 3 end subscript over denominator 4 pi epsilon subscript 0 end subscript end fraction k comma$ where k is

physics-General

parallel

Figure shows three spherical and equipotential surfaces A, B and C round a point charge q. The potential difference $V subscript A end subscript minus V subscript B end subscript equals V subscript B end subscript minus V subscript C end subscript$ . If $t subscript 1 end subscript$ and $t subscript 2 end subscript$ be the distance between them. Then

Figure shows three spherical and equipotential surfaces A, B and C round a point charge q. The potential difference $V subscript A end subscript minus V subscript B end subscript equals V subscript B end subscript minus V subscript C end subscript$ . If $t subscript 1 end subscript$ and $t subscript 2 end subscript$ be the distance between them. Then

physics-General

Charges +q and –q are placed at points A and B respectively which are a distance $2 L$ apart, C is the mid-point between A and B. The work done in moving a charge+ $Q$ along the semicircle CRD is

Charges +q and –q are placed at points A and B respectively which are a distance $2 L$ apart, C is the mid-point between A and B. The work done in moving a charge+ $Q$ along the semicircle CRD is

physics-General

Consider three concentric shells of metal A, B and C are having radii a, b and c respectively as shown in the figure $left parenthesis a less than b less than c right parenthesis.$ Their surface charge densities are $sigma comma negative sigma a n d sigma$ respectively. Calculate the electric potential on the surface of shell A

Consider three concentric shells of metal A, B and C are having radii a, b and c respectively as shown in the figure $left parenthesis a less than b less than c right parenthesis.$ Their surface charge densities are $sigma comma negative sigma a n d sigma$ respectively. Calculate the electric potential on the surface of shell A

physics-General

parallel

card img

With Turito Academy.

card img

With Turito Foundation.

card img

Get an Expert Advice From Turito.

Turito Academy

card img

With Turito Academy.

Test Prep

card img

With Turito Foundation.