Determine order and degree (if defined) of differential equations given
It is given that equation is
⇒ y”” + sin(y’’’) = 0
We can see that the highest order derivative present in the differential is y””.
Thus, its order is four. The given differential equation is not a polynomial equation in its derivative.
Therefore, its degree is not defined.
Determine order and degree (if defined) of differential equations given
y′ + 5y = 0
It is given that equation is y’ + 5y = 0
We can see that the highest order derivative present in the differential is y’.
Thus, its order is one. It is polynomial equation in y’. The highest power raised to y’ is 1.
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
It is given that equation is
We can see that the highest order derivative present in the given differential equation is
Thus, its order is two. It is polynomial equation in and
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
It is given that equation is
We can see that the highest order derivative present in the given differential equation is.
Thus, its order is two. The given differential equation is not a polynomial equation in its derivative.
Therefore, its degree is not defined.
Determine order and degree (if defined) of differential equations given
It is given that equation is
We can see that the highest order derivative present in the given differential equation is
Thus, its order is two. It is polynomial equation in and the power is 1.
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
(y″′)2 + (y″)3 + (y′)4 + y5 = 0
It is given that equation is (y”’)2 + (y”)3 +(y’)4 + y5 = 0
We can see that the highest order derivative present in the differential is y”’.
Thus, its order is three. It is polynomial equation in y”’, y” and y’
So, the highest power raised to y”’ is 2.
Therefore, its degree is two.
Determine order and degree (if defined) of differential equations given
y″′ +2y” + y’ = 0
It is given that equation is y″′ +2y” + y’ = 0
We can see that the highest order derivative present in the differential is y”’.
Thus, its order is three. It is polynomial equation in y”’, y” and y’
So, the highest power raised to y”’ is 1.
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
y′ + y = ex
It is given that equation is y’ + y = ex
⇒ y’ + y – ex = 0
We can see that the highest order derivative present in the differential is y’.
Thus, its order is one. It is polynomial equation in y’
So, the highest power raised to y’ is 1.
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
y″ + (y′) + 2y = 0
It is given that equation is y’’ + (y’)2 + 2y = 0
We can see that the highest order derivative present in the differential is y”.
Thus, its order is two. It is polynomial equation in y” and y’
So, the highest power raised to y” is 1.
Therefore, its degree is one.
Determine order and degree (if defined) of differential equations given
y″ + 2y′ + sin y = 0
It is given that equation is y’’ + 2y’ + siny = 0
We can see that the highest order derivative present in the differential is y”.
Thus, its order is two. It is polynomial equation in y” and y’
So, the highest power raised to y” is 1.
Therefore, its degree is one.
The degree of the differential equation
is
A. 3
B. 2
C. 1
D. not defined
It is given that equation is
We can see that the highest order derivative present in the given differential equation is.
Thus, its order is three.
The given differential equation is not a polynomial equation in its derivative.
Therefore, its degree is not defined.
The order of the differential equation
is
A. 2
B. 1
C. 0
D. not defined
It is given that equation is
We can see that the highest order derivative present in the given differential equation is .
Thus, its order is two.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y = ex + 1 : y′′ – y′ = 0
It is given that y = ex + 1
Now, differentiating both sides w.r.t. x, we get,
Now, Again, differentiating both sides w.r.t. x, we get,
⇒ y” = ex
Now, Substituting the values of y’ and y” in the given differential equations, we get,
y” – y’ = ex - ex = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y = x2 + 2x + C : y′ – 2x – 2 = 0
It is given that y = x2 + 2x + C
Now, differentiating both sides w.r.t. x, we get,
⇒ y’ = 2x + 2
Now, Substituting the values of y’ in the given differential equations, we get,
y’ – 2x -2 = 2x + 2 – 2x - 2 = 0 = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y = cos x + C : y′ + sin x = 0
It is given that y = cosx + C
Now, differentiating both sides w.r.t. x, we get,
⇒ y’ = -sinx
Now, Substituting the values of y’ in the given differential equations, we get,
y’ + sinx = -sinx + sinx = 0 = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
It is given that y =
Now, differentiating both sides w.r.t. x, we get,
Therefore, LHS = RHS
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y = Ax : xy′ = y (x ≠ 0)
It is given that y = Ax
Now, differentiating both sides w.r.t. x, we get,
⇒ y’ = A
Now, Substituting the values of y’ in the given differential equations, we get,
xy’ = x.A = Ax = y = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y = x sin x : xy′ = y + x (x ≠ 0 and x > y or x < – y)
It is given that y = xsinx
Now, differentiating both sides w.r.t. x, we get,
⇒ y’ = sinx + xcosx
Now, Substituting the values of y’ in the given differential equations, we get,
LHS = xy’ = x(sinx + xcosx)
= xsinx + x2cosx
= y +
= RHS
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
xy = log y + C :
It is given that xy = log y + C
Now, differentiating both sides w.r.t. x, we get,
⇒ y + xy’ =
⇒ y2 + xyy’ = y’
⇒ (xy – 1)y’ = -y2
⇒ y’ =
Thus, LHS = RHS
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
y – cos y = x : (y sin y + cos y + x)y′ = y
It is given that y – cosy = x
Now, differentiating both sides w.r.t. x, we get,
⇒ y’(1 + siny) = 1
⇒ y’ =
Now, Substituting the values of y’ in the given differential equations, we get,
LHS = (ysiny + cosy + x)y’
= y = RHS
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
x + y = tan–1y : y2y′ + y2 + 1 = 0
It is given that x + y = tan-1y
Now, differentiating both sides w.r.t. x, we get,
Now, Substituting the values of y’ in the given differential equations, we get,
LHS = y2y’ + y2 + 1 =
= -1 – y2 + y2 + 1
= 0 = RHS
Therefore, the given function is the solution of the corresponding differential equation.
In each of the question verify that the given functions (explicit or implicit) is a solution of the corresponding differential equation:
It is given that
Now, differentiating both sides w.r.t. x, we get,
Now, Substituting the values of y’ in the given differential equations, we get,
LHS =
= x –x = 0 = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
The number of arbitrary constants in the general solution of a differential equation of fourth order are:
A. 0
B. 2
C. 3
D. 4
As we know that the number of constant in the general solution of a differential equation of order n is equal to its order.
Thus, the number of constant in the general equation of fourth order differential equation is four.
The number of arbitrary constants in the particular solution of a differential equation of third order are:
A. 3
B. 2
C. 1
D. 0
In a particular solution of a differential equation, there is no arbitrary constant.
In each of the question, form a differential equation representing the given family of curves by eliminating arbitrary constants a and b.
The given equation is
Now, differentiating both sides w.r.t x, we get,
Now, again differentiating both sides, we get,
⇒ y’’ = 0
Therefore, the required differential equation is y’’ = 0.
In each of the question, form a differential equation representing the given family of curves by eliminating arbitrary constants a and b.
y2 = a(b2 – x2)
The given equation is y2 = a(b2 – x2)
Now, differentiating both sides w.r.t x, we get,
⇒ 2yy’ = -2ax
⇒ yy’ = -ax -------(1)
Now, again differentiating both sides, we get,
y’.y’ +yy’’ = -a
⇒ (y’)2 + yy” = -a --------(2)
Now, dividing equation (2) by (1), we get,
⇒ xyy” + x(y’)2 – yy” = 0
Therefore, the required differential equation is xyy” + x(y’)2 – yy” = 0.
In each of the question, form a differential equation representing the given family of curves by eliminating arbitrary constants a and b.
y = a e3x + b e–2x
It is given that y = ae3x + be-2x --------(1)
Now, differentiating both side we get,
y’ = 3ae3x - 2be-2x --------(2)
Now, again differentiating both sides, we get,
y’’ = 9ae3x + 4be-2x -------(3)
Now, let us multiply equation (1) with 2 and then adding it to equation (2), we get,
(2ae3x + 2be-2x) + (3ae3x - 2be-2x) = 2y – y’
⇒ 5ae3x = 2y + y’
Now, let us multiply equation (1) with 3 and subtracting equation (2), we get
(3ae3x + 3be-2x) - (3ae3x - 2be-2x) = 3y – y’
⇒ 5be-2x = 3y - y’
y” = 9. +4
⇒ y” = 6y + y’
⇒ y” – y’ - 6y = 0
Therefore, the required differential equation is y” – y’ - 6y = 0.
In each of the question, form a differential equation representing the given family of curves by eliminating arbitrary constants a and b.
y = e2x (a + bx)
It is given y = e2x(a + bx) -------(1)
Now, differentiating both side w.r.t. x, we get,
y’ = 2e2x(a + bx) + e2x.b ------(2)
Now, let us multiply equation (1) with 2 and then subtracting it to equation (2), we get,
y’ – 2y = e2x(2a +2bx + b) – e2x(2a + 2bx)
⇒ y’ – 2y = be2x ---------(3)
Now, again differentiating both sides w.r.t. x, we get,
y” – 2y’ = 2be2x ------(4)
Dividing equation (4) by equation (3), we get,
⇒ y” – 2y’ = 2y’ – 4y
⇒ y” – 4y’ – 4y = 0
Therefore, the required differential equation is y” – 4y’ - 4y = 0.
In each of the question, form a differential equation representing the given family of curves by eliminating arbitrary constants a and b.
y = ex (a cos x + b sin x)
It is given that y = ex(acosx + bsinx) ------(1)
Now, differentiating both w.r.t. x, we get,
y’ = ex(acosx + bsinx) + ex(-asinx + bcosx)
⇒ y’ = ex[(a + b)cosx – (a – b)sinx)] ------(2)
Again, differentiating both sides w.r.t. x, we get,
y” = ex[(a + b)cosx – (a – b)sinx)] + ex[-(a + b)sinx – (a – b)cosx)]
⇒ y” = ex[2bcosx – 2asinx]
⇒ y” = 2ex(bcosx – asinx) ----(3)
Adding equation (1) and (3), we get,
⇒ 2y + y” = 2y’
Therefore, the required differential equation is 2y + y” = 2y’= 0.
Form the differential equation of the family of circles touching the y-axis at origin.
The center of the circle touching the y- axis at orgin lies on the x – axis.
Let (a,0) be the centre of the circle.
Thus, it touches the y – axis at orgin, its radius is a.
Now, the equation of the circle with centre (a,0) and radius (a) is
(x –a)2 – y2 = a2
⇒ x2 + y2 = 2ax
Now, differentiating both sides w.r.t. x , we get,
2x + 2yy’ = 2a
⇒ x + yy’ = a
Now, on substituting the value of a in the equation, we get,
x2 + y2 = 2(x + yy’)x
⇒ 2xyy’ + x2 = y2
Therefore, the required differential equation is 2xyy’ + x2 = y2 .
Form the differential equation of the family of parabolas having vertex at origin and axis along positive y-axis.
We know that the equation of the parabola having the vertex at origin and the axis along the positive y- axis is
x2 = 4ay ------(1)
Now, differentiating equation (1) w.r.t. x, we get,
2x = 4ay’ -----(2)
On dividing equation (2) by equation (1), we get,
⇒ xy’ = 2y
⇒ xy’ – 2y = 0
Therefore, the required differential equation is xy’ – 2y = 0.
Form the differential equation of the family of ellipses having foci on y-axis and centre at origin.
We know that the equation of the family of ellipses having foci on y – axis and the centre at origin is
-------(1)
Now, differentiating equation (1) w.r.t. x, we get,
----(2)
Now, again differentiating w.r.t. x, we get,
Let us substitute the value in eq. (2), we get,
⇒ -x(y’)2 – xyy” + yy’ = 0
⇒ xyy” + x(y’)2 – yy’ = 0
Therefore, the required differential equation is xyy” + x(y’)2 – yy’ = 0.
Form the differential equation of the family of hyperbolas having foci on x-axis and centre at origin.
We know that the equation of the family of hyperbolas having foci on x – axis and the centre at origin is
-------(1)
Now, differentiating equation (1) w.r.t. x, we get,
--------(2)
Now, again differentiating w.r.t. x, we get,
Let us substitute the value in eq. (2), we get,
⇒ x(y’)2 + xyy” - yy’ = 0
⇒ xyy” + x(y’)2 – yy’ = 0
Therefore, the required differential equation is xyy” + x(y’)2 – yy’ = 0.
Form the differential equation of the family of circles having centre on y-axis and radius 3 units.
Let the centre of the circle on y – axis be (0,b).
We know that the differential equation of the family of circles with centre at (0, b) and radius 3 is: x2 + (y- b)2 = 32
⇒ x2 + (y- b)2 = 9 ----(1)
Now, differentiating both sides w.r.t. x, we get,
2x + 2(y – b).y’ = 0
⇒ (y – b). y’ = x
⇒ y – b =
Thus, substituting the value of ( y – b) in equation (1), we get,
⇒ x2((y’)2 + 1) = 9(y’)2
⇒ (x2 – 9)(y’)2 + x2 = 0
Therefore, the required differential equation is (x2 – 9)(y’)2 + x2 = 0
Which of the following differential equations has y = c1ex + c2e–x as the general solution?
A.
B.
C.
D.
It is given that y = c1ex + c2e-x
Now, differentiating both sides w.r.t. x, we get,
Again, differentiating both sides w.r.t. x, we get,
Therefore, the required differential equation is .
Which of the following differential equations has y = x as one of its particular solution?
A.
B.
C.
D.
It is given that that y = x
Now, differentiating both sides w.r.t. x, we get,
Again, differentiating both sides w.r.t. x, we get,
Now, substitute the value of in the given options, we will see that the differential equation in option (C) is correct.
= -x2 + x2
= 0
For each of the differential equations in question, find the general solution:
For each of the differential equations in question, find the general solution:
⇒
For each of the differential equations in question, find the general solution:
dy = (1 - y) dx
Separating variables
⇒ -log(1-y) = x + logc
⇒ -log(1-y) - logc = x
⇒ log (1-y)c = -x
Or
⟹
For each of the differential equations in question, find the general solution:
sec2x tan y dx + sec2y tan x dy
Dividing both sides by (tanx)(tany)
Integrating both sides,
⇒ lettan x = t &tany = u
⇒ log t = -log u + log c
Or,
⇒ log(tanx) = -log(tany) + log c
Or
⇒ (tan x) (tan y) = c
For each of the differential equations in question, find the general solution:
(ex + e–x)dy – (ex – e–x)dx = 0
Integrating both sides,
Let ( = t
Then,
So,
⇒ y = log t
Or,
+ c
For each of the differential equations in question, find the general solution:
Separating variables,
Integrating both sides,
For each of the differential equations in question, find the general solution:
y log y dx – x dy = 0
y log y dx – x dy = 0
⇒ (y log y) dx = xdy
Separating variables,
Integrating both sides,
⇒ let logy = t
⇒ log x + log c = log t
Or,
⇒ log x + log c = log (log y)
⇒ log cx = log y
Or,
⇒ log y = cx
For each of the differential equations in question, find the general solution:
Separating variables,
Or,
Integrating both sides,
Letbe a constant,
Or,
0r,
For each of the differential equations in question, find the general solution:
Separating variables,
Integrating both sides,
Now to integrate we have to multiply it by 1
because,
∵ { - i)
So,
According to i)
Let u be and v be 1
We can take the values of u and v from the formula (I.L.A.T.E)
So,
Or
putting the value of t,
For each of the differential equations in question, find the general solution:
extan y dx + 1(1 – ex)sec2y dy = 0
Separating the variables,
Now Integrating both sides,
Let &
Then,
Then,
Or,
⇒ log t = log u + log c
Substituting the values of t and u on above equation.
Or,
For each of the differential equations in question, find a particular solution satisfying the given condition:
(x3 + x2 + x + 1) dy/dx = 2x2 + x, y = 1 when x = 0
(
Separating variables,
Integrating both sides,
Integrating it partially,
Now comparing the coefficients of
⇒ A + B = 2
⇒ B + C = 1
⇒ A + C = 0
Solving them we will get the values of A,B,C
Putting the values of A,B,C in i)
So,
Then, 2xdx = dt
or,
Or,
Now, we are given that y = 1 when x = 0
So,
C = 1
Putting the value of c in ii)
For each of the differential equations in question, find a particular solution satisfying the given condition:
x(x2 – 1) dy/dx = 1; y = 0 when x = 0
Separating variables,
Or,
Integrating both sides,
Now let,
Or
Now comparing the values of A,B,C
A + B + C = 0
B-C = 0
A = -1
Solving these we will get that
Now putting the values of A,B,C in ii)
Now integrating it,
Now we are given that
Or,
Now putting the value of
Then,
For each of the differential equations in question, find a particular solution satisfying the given condition:
cos dy/dx = a; y = 2 when x = 0
Separating variables,
Now y = 2 when x = 0
⇒ 2 = 0 + c
⇒ c = 2
Putting the value of ini)
For each of the differential equations in question, find a particular solution satisfying the given condition:
dy/dx = y tan x; y = 1 when x = 0
Separating variables,
Integrating both sides,
⇒ log y = -log (cos x) + log c
Or,
⇒ log y = log (sec x) + log c
⇒ log y = log c (sec x)
⇒ y = c (sec x) -i)
Now we are given that y = 1 when x = 0
⇒ 1 = c (sec 0)
⇒ 1 = c × 1
⇒ c = 1
Putting the value of c in i)
⇒ y = sec x
Find the equation of a curve passing through the point (0, 0) and whose differential equation is y′ = ex sin x
To find the equation of a curve that passes through point(0,0) and has differential equation
So, we need to find the general solution of the given differential equation and the put the given point in to find the value of constant.
Separating variables,
Integrating both sides,
{Using the formula, )
Now let
integrating for .
Or,
Or,
Now we are given that the curve passes through point(0,0)
Putting the value of C in ii)
So,
So the required equations become,
For the differential equation find the solution curve passing through the point (1, –1).
For this question, we need to find the particular solution at point(1,-1) for the given differential equation.
Given differential equation is
Separating variables,
Or,
Integrating both sides,
Now separating like terms on each side,
Or,
Now we are given that, the curve passes through (1, -1)
⇒ -2-c = log (1)
⇒ c = -2 + 0 (∵ log(1) = 0)
So c = -2
Putting the value of c in
Find the equation of a curve passing through the point (0, –2) given that at any point (x, y) on the curve, the product of the slope of its tangent and y coordinate of the point is equal to the x coordinate of the point.
We know that slope of a tangent is =
So we are given that the product of the slope of its tangent and y coordinate of the point is equal to the x coordinate of the point.
Now separating variables,
⇒ ydy = xdx
Integrating both sides,
Now the curve passes through (0, -2).
∴ 4-0 = 2c
⇒ c = 2
Putting the value of c in i)
At any point (x, y) of a curve, the slope of the tangent is twice the slope of the line segment joining the point of contact to the point (– 4, –3). Find the equation of the curve given that it passes through (–2, 1).
We know that (x,y) is the point of contact of curve and its tangent.
slope(m1)for line joining (x,y) and (-4,-3) is
Also we know that slope of tangent of a curve is .
Now, according to the question,
(m2) = 2(m1)
Separating variables,
Integrating both sides,
⇒ log(y + 3) = 2log(x + 4) + log c
Now, this equation passes thorough the point (-2,1).
⇒ 4 = 4c
⇒ c = 1
Substitute the value of c in iii)
The volume of spherical balloon being inflated changes at a constant rate. If initially its radius is 3 units and after 3 seconds it is 6 units. Find the radius of balloon after t seconds.
Let the rate of change of the volume of the balloon be k. (k is a constant)
Or,
Integrating both sides,
Now, given that
At t = 0, r = 3:
⇒ 4π × 33 = 3(k×0 + c)
⇒ 108π = 3c
⇒ c = 36π
At t = 3, r = 6:
⇒ k = 84π
Substituting the values of k and c in i)
So the radius of balloon after t seconds is
In a bank, principal increases continuously at the rate of r% per year. Find the value of r if Rs 100 double itself in 10 years (loge2 = 0.6931).
let t be time
p be principal
r be rate of interest
according the information principal increases at the rate of r% per year.
Separating variables,
Integrating both sides,
Given that t = 0, p = 100.
Now, if t = 10, then p = 2×100 = 200
So,
So r is 6.93%.
In a bank, principal increases continuously at the rate of 5% per year. An amount of Rs 1000 is deposited with this bank, how much will it worth after 10 years (e0.5 = 1.648).
Let p and t be principal and time respectively.
Given that principal increases continuously at rate of 5% per year.
Separating variables,
Integrating both sides,
When t = 0, p = 1000
At t = 10
So after 10 years the total amount would be Rs.1648
In a culture, the bacteria count is 1,00,000. The number is increased by 10% in 2 hours. In how many hours will the count reach 2,00,000, if the rate of growth of bacteria is proportional to the number present?
let y be the number of bacteria at any instant t.
Given that the rate of growth of bacteria is proportional to the number present
Separating variables,
Integrating both sides,
⇒ log y = kt + c -i)
Let y’ be the number of bacteria at t = 0.
⇒ log y’ = c
Substituting the value of c in
⇒ log y = kt + log y’
⇒ log y- log y’ = kt
Also, given that number of bacteria increases by 10% in 2 hours.
Substituting this value in
So, becomes
Now, let the time when number of bacteria increase from 100000 to 200000 be t’.
So from
So bacteria increases from 100000 to 200000 in hours.
The general solution of the differential equation is
A. ex + e–y = C
B. ex + ey = C
C. e–x + ey = C
D. e–x + e–y = C
separating variables
Integrating both sides
Or,
(c is a constant)
So the correct option is A.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
(x2 + xy)dy = (x2 + y2)dx
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
(x2 + xy)dy = (x2 + y2)dx
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating on both side,
- v - 2log|1 - v| = log|x| + logc
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
v = logx + C
y = xlogx + Cx
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
(x – y)dy – (x + y)dx = 0
(x - y)dy = (x + y)dx
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
(x - y)dy – (x + y)dx = 0
To make it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides we get,
2vdv = dt
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
(x2 – y2)dx + 2xy dy = 0
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
Put 1 + v2 = t
2vdv = dt
log(t)
∴ log(1 + v2) = -logx + logC (∴ From (i) eq.)
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
log secv – logv = 2logkx
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x= kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both side, we get
log(cosecv – cotv) = -logx + logC
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
Put, logv – 1 = t
logt
log(logv - 1)
∴ log(logv - 1) – log(v) = log(x) + log(c) (From (i) eq.)
The required solution of the differential equation.
In each of the question, show that the given differential equation is homogeneous and solve each of them.
Here, putting x = kx and y = ky
= k0f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
x = vy
Differentiation eq. with respect to x, we get
Integrating both sides, we get
Put ev + v = t
(ev + 1)dv = dt
logt
log(ev + v)
∴ log(ev + v) = - logy + logC (∴ From (i) eq.)
Multiply by y on both side, we get
yex/y + x = C
x + yex/y = C
The required solution of the differential equation.
For each of the differential equations in question, find the particular solution satisfying the given condition:
(x + y)dy + (x – y) dx = 0; y = 1 when x = 1
(x + y)dy + (x - y)dx = 0
Here, putting x= kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
(x + y)dy + (x - y)dx = 0
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
y = 1 when x = 1
The required solution of the differential equation.
For each of the differential equations in question, find the particular solution satisfying the given condition:
x2dy + (xy + y2)dx = 0; y = 1 when x = 1
x2dy + (xy + y2)dx = 0
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
x2dy + (xy + y2)dx = 0
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
y = 1 when x = 1
3x2y = y + 2x
y + 2x = 3x2y
The required solution of the differential equation.
For each of the differential equations in question, find the particular solution satisfying the given condition:
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
∫cosec2vdv = - logx – logC
-cot v = - logx – logC
cot v = logx + logC
1 = C
e1 = C
The required solution of the differential equation.
For each of the differential equations in question, find the particular solution satisfying the given condition:
y = 0 when x = 1
Here, putting x= kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
- cosv = - logx + C
y = 0 when x = 1
- 1 = C
The required solution of the differential equation.
For each of the differential equations in question, find the particular solution satisfying the given condition:
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equation is homogeneous.
To solve it we make the substitution.
y = vx
Differentiating eq. with respect to x, we get
Integrating both sides, we get
y = 2 when x = 1
- 1 = C
The required solution of the differential equation.
A homogeneous differential equation of the from can be solved by making the substitution.
A. y = vx
B. v = yx
C. x = vy
D. x = v
Therefore, we shall substitute,
x = vy
A homogeneous differential equation of the from can be solved by making the substitution.
A. (4x + 6y + 5)dy – (3y + 2x + 4)dx = 0
B. (xy)dx – (x3 + y3) dy = 0
C. (x3 + 2y2)dx + 2xy dy = 0
D. y2dx + (x2 – xy – y2)dy = 0
(A) (4x + 6y + 5)dy – (3y + 2x + 4)dx = 0
It cannot be homogeneous as we can see that (4x + 6y + 5) is not homogeneous.
(B) (xy)dx – (x3 + y3)dy = 0
It cannot be homogeneous as the xy which multiplies with dx and x3 + y3 which multiplies with dy are not of same degree.
(C) (x3 + 2y2)dx + 2xy dy = 0
Similarly, it cannot be homogeneous as the x3 + 2y2 which multiplies with dx and 2xy which multiplies with dy are not of same degree.
(D) y2dx + (x2 – xy – y2)dy = 0
Here, putting x = kx and y = ky
= k0.f(x,y)
Therefore, the given differential equations is homogeneous.
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = 2 and Q = sinx)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
--------(1)
Let I =
Now, putting the value of I in (1), we get,
Therefore, the required general solution of the given differential equation is
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = 3 and Q = )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
⇒ ye3x = ex + C
⇒ y = e-2x + Ce-3x
Therefore, the required general solution of the given differential equation is y = e-2x + Ce-3x
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q = )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
Therefore, the required general solution of the given differential equation is .
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = secx and Q = tanx)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
⇒ y(secx + tanx) = secx + tanx – x+ C
Therefore, the required general solution of the given differential equation is
y(secx + tanx) = secx + tanx – x+ C.
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q =)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
-----------(1)
Now, Let t = tanx
⇒ sec2xdx = dt
Thus, the equation (1) becomes,
⇒ tetanx = (t – 1)et + C
⇒ tetanx = (tanx – 1)etanx + C
⇒ y = (tanx -1) + C e-tanx
Therefore, the required general solution of the given differential equation is
y = (tanx -1) + C e-tanx.
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q =xlogx)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
Therefore, the required general solution of the given differential equation
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q =)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
------------------(1)
Now,
Now, substituting the value in (1), we get,
Therefore, the required general solution of the given differential equation is
For each of the differential equations given in question, find the general solution:
(1 + x2)dy + 2xy dx = cot x dx (x ≠ 0)
It is given that
This is equation in the form of (where, p = and Q = )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
Therefore, the required general solution of the given differential equation is
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q = 1 )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
x(I.F.) =
⇒ y(xsinx) = -xcosx + sinx + C
⇒
⇒
Therefore, the required general solution of the given differential equation is
.
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = -1 and Q = y )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
x(I.F.) =
=> x = - y – 1 + Cey
=> x + y + 1 = Cey
Therefore, the required general solution of the given differential equation is
x + y + 1 = Cey.
For each of the differential equations given in question, find the general solution:
y dx + (x – y2)dy = 0
It is given that
This is equation in the form of (where, p = and Q = y )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
x(I.F.) =
Therefore, the required general solution of the given differential equation is .
For each of the differential equations given in question, find the general solution:
It is given that
This is equation in the form of (where, p = and Q = 3y )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
x(I.F.) =
⇒ x = 3y2 + Cy
Therefore, the required general solution of the given differential equation is x = 3y2 + Cy.
For each of the differential equations given in question, find a particular solution satisfying the given condition:
It is given that
This is equation in the form of (where, p = 2tanx and Q =sinx )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
----------------(1)
Now, it is given that y = 0 at x =
⇒ 0 = 2 + C
⇒ C = -2
Now, Substituting the value of C = -2 in (1), we get,
⇒ y = cosx – 2cos2x
Therefore, the required general solution of the given differential equation is
y = cosx – 2cos2x.
For each of the differential equations given in question, find a particular solution satisfying the given condition:
It is given that
This is equation in the form of (where, p = and Q = )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
----------------(1)
Now, it is given that y = 0 at x = 1
0 = tan-1 1+ C
⇒ C =
Now, Substituting the value of C = in (1), we get,
Therefore, the required general solution of the given differential equation is
For each of the differential equations given in question, find a particular solution satisfying the given condition:
It is given that
This is equation in the form of (where, p = -3cotx and Q = sin2x)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
⇒ y cosec3x = 2cosecx + C
⇒ y =
⇒ y = -2sin2x + Csin3x--------------(1)
Now, it is given that y = 2 when x =
Thus, we get,
2 = -2 + C
⇒ C = 4
Now, Substituting the value of C = 4 in (1), we get,
y = -2sin2x + 4sin3x
⇒ y = 4sin3x - 2sin2x
Therefore, the required general solution of the given differential equation is
y = 4sin3x - 2sin2x.
Find the equation of a curve passing through the origin given that the slope of the tangent to the curve at any point (x, y) is equal to the sum of the coordinates of the point.
Let F(x,y) be the curve passing through origin and let (x,y) be a point on the curve.
We know the slope of the tangent to the curve at (x,y) is .
According to the given conditions, we get,
This is equation in the form of (where, p = -1 and Q = x )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
--------(1)
Now,
Thus, from equation (1), we get,
⇒ y = -(x+1) + Cex
⇒ x + y + 1 = Cex -----(2)
Now, it is given that curve passes through origin.
Thus, equation (2) becomes:
1 = C
⇒ C = 1
Substituting C = 1 in equation (2), we get,
x + y – 1 = ex
Therefore, the required general solution of the given differential equation is
x + y -1 = ex
Find the equation of a curve passing through the point (0, 2) given that the sum of the coordinates of any point on the curve exceeds the magnitude of the slope of the tangent to the curve at that point by 5.
Let F(x,y) be the curve and let (x,y) be a point on the curve.
We know the slope of the tangent to the curve at (x,y) is .
According to the given conditions, we get,
This is equation in the form of (where, p = -1 and Q = x - 5)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
------------(1)
Now,
Thus, from equation (1), we get,
⇒ y = 4 – x + Cex
⇒ x + y – 4 = Cex
Now, it is given that curve passes through (0,2).
Thus, equation (2) becomes:
0 + 2 – 4 = C e0
⇒ - 2 = C
⇒ C = -2
Substituting C = -2 in equation (2), we get,
x + y – 4 =-2ex
⇒ y = 4 – x – 2ex
Therefore, the required general solution of the given differential equation is
y = 4 – x – 2ex
The Integrating Factor of the differential equation is
A. e–x
B. e–y
C. 1/x
D. x
It is given that
This is equation in the form of (where, p = and Q =2x)
Now, I.F. =
The Integrating Factor of the differential equation
is
A.
B.
C.
D.
It is given that
This is equation in the form of (where, p = and Q = )
Now, I.F. =
For each of the differential equations given below, indicate its order and degree (if defined).
It is given that equation is
We can see that the highest order derivative present in the differential is .
Thus, its order is two. It is polynomial equation in . The highest power raised to is 1.
Therefore, its degree is one.
For each of the differential equations given below, indicate its order and degree (if defined).
It is given that equation is
We can see that the highest order derivative present in the differential is.
Thus, its order is one. It is polynomial equation in . The highest power raised to is 3.
Therefore, its degree is three.
For each of the differential equations given below, indicate its order and degree (if defined).
It is given that equation is
We can see that the highest order derivative present in the differential is .
Thus, its order is four. The given differential equation is not a polynomial equation.
Therefore, its degree is not defined.
For each of the exercises given below, verify that the given function (implicit or explicit) is a solution of the corresponding differential equation.
xy = a ex + b e–x + x2 :
It is given that xy = a ex + b e–x + x2
Now, differentiating both sides w.r.t. x, we get,
Now, Again differentiating both sides w.r.t. x, we get,
Now, Substituting the values of ’ and in the given differential equations, we get,
LHS =
= x(aex +be-x + 2) + 2(aex - be-x + 2) –x(aex +be-x + x2) + x2 – 2
= (axex +bxe-x + 2x) + 2(aex - be-x + 2) –x(aex +be-x + x2) + x2 – 2
= 2aex -2be-x +x2 + 6x -2
≠ 0
⇒ LHS ≠ RHS.
Therefore, the given function is not the solution of the corresponding differential equation.
For each of the exercises given below, verify that the given function (implicit or explicit) is a solution of the corresponding differential equation.
y = ex (a cos x + b sin x) :
It is given that y = ex(acosx + bsinx) = aexcosx + bexsinx
Now, differentiating both sides w.r.t. x, we get,
Now, again differentiating both sides w.r.t. x, we get,
Now, Substituting the values of ’ and in the given differential equations, we get,
LHS =
=2ex(bcosx – asinx) -2ex[(a + b)cosx + (b –a ) sinx] + 2ex(acosx + bsinx)
=ex[(2bcosx – 2asinx) - (2acosx + 2bcosx) - (2bsinx – 2asinx) + (2acosx + 2bsinx)]
= ex[(2b – 2a – 2b + 2a)cosx] + ex[(-2a – 2b + 2a + 2bsinx]
= 0 = RHS.
Therefore, the given function is the solution of the corresponding differential equation.
For each of the exercises given below, verify that the given function (implicit or explicit) is a solution of the corresponding differential equation.
y = x sin 3x :
It is given that y = xsin3x
Now, differentiating both sides w.r.t. x , we get,
Now, again differentiating both sides w.r.t. x, we get,
Now, substituting the value of in the LHS of the given differential equation, we get,
= (6.cos3x – 9xsin3x) + 9xsin3x – 6cos3x
= 0 = RHS
Therefore, the given function is the solution of the corresponding differential equation.
For each of the exercises given below, verify that the given function (implicit or explicit) is a solution of the corresponding differential equation.
x2 = 2y2 log y :
It is given that x2 = 2y2 log y
Now, differentiating both sides w.r.t. x, we get,
2x = 2.
Now, substituting the value of in the LHS of the given differential equation, we get,
= xy –xy
= 0
Therefore, the given function is the solution of the corresponding differential equation.
Form the differential equation representing the family of curves given by (x – a)2 + 2y2 = a2, where a is an arbitrary constant.
It is given that (x – a)2 + 2y2 = a2
⇒ x2 + a2 – 2ax + 2y2 = a2
⇒ 2y2 = 2ax – x2 ---------(1)
Now, differentiating both sides w.r.t. x, we get,
- ---------(2)
So, equation (1), we get,
2ax = 2y2 + x2
On substituting this value in equation (3), we get,
Therefore, the differential equation of the family of curves is given as .
Prove that x2 – y2 = c (x2 + y2)2 is the general solution of differential equation (x3–3xy2) dx = (y3–3x2y)dy, where c is a parameter.
It is given that (x3–3xy2) dx = (y3–3x2y)dy
- --------(1)
Now, let us take y = vx
Now, substituting the values of y and in equation (1), we get,
On integrating both sides we get,
--------(2)
Now,
---------(3)
Let
⇒
⇒
⇒
Now,
Let v2 = p
Now, substituting the values of I1 and I2 in equation (3), we get,
Thus, equation (2), becomes,
⇒ (x2 – y2)2 = C’4(x2 + y2 )4
⇒ (x2 – y2) = C’2(x2 + y2 )
⇒ (x2 – y2) = C(x2 + y2 ), where C = C’2
Therefore, the result is proved.
Form the differential equation of the family of circles in the first quadrant which touch the coordinate axes.
We know that the equation of a circle in the first quadrant with centre (a, a) and radius a which touches the coordinate axes is :
(x -a)2 + (y –a)2 = a2 -----------(1)
Now differentiating above equation w.r.t. x, we get,
2(x-a) + 2(y-a) = 0
⇒ (x – a) + (y – a)y’ = 0
⇒ x – a +yy’ – ay’ = 0
⇒ x + yy’ –a(1+y’) = 0
⇒ a =
Now, substituting the value of a in equation (1), we get,
⇒ (x - y)2.y’2 + (x – y)2 = (x + yy’)2
⇒ (x – y)2[1 + (y’)2] = (x + yy’)2
Therefore, the required differential equation of the family of circles is
(x – y)2[1 + (y’)2] = (x + yy’)2
Find the general solution of the differential equation
It is given that
On integrating, we get,
⇒ sin-1x + sin-1y = C
Show that the general solution of the differential equation is given by (x + y + 1) = A (1 – x – y – 2xy), where A is parameter.
It is given that
On integrating both sides, we get,
Let
Then,
Now, let A = , then, we have,
Find the equation of the curve passing through the point whose differential equation is sin x cos y dx + cos x sin y dy = 0.
It is given that sin x cos y dx + cos x sin y dy = 0
⇒ tanxdx + tanydy = 0
So, on integrating both sides, we get,
log(secx) + log(secy) = logC
⇒ log(secx.secy) = log C
⇒ secx.secy = C
The curve passes through point
Thus, 1× = C
⇒ C =
On substituting C = in equation (1), we get,
secx.secy =
Therefore, the required equation of the curve is
Find the particular solution of the differential equation (1 + e2x) dy + (1 + y2) ex dx = 0, given that y = 1 when x = 0.
It is given that (1 + e2x) dy + (1 + y2) ex dx = 0
On integrating both sides, we get,
------(1)
Let ex = t
⇒ e2x = t2
⇒ exdx = dt
Substituting the value in equation (1), we get,
⇒ tan-1 y + tan-1 t = C
⇒ tan-1 y + tan-1 (ex) = C -------(2)
Now, y =1 at x = 0
Therefore, equation (2) becomes:
tan-1 1 + tan-1 1 = C
Substituting in (2), we get,
tan-1 y + tan-1 (ex) =
Solve the differential equation
It is given that
------(1)
Let
Differentiating it w.r.t. y, we get,
------(2)
From equation (1) and equation (2), we get,
⇒ dz = dy
On integrating both sides, we get,
z = y + C
Find a particular solution of the differential equation (x – y) (dx + dy) = dx – dy, given that y = –1, when x = 0. (Hint: put x – y = t)
It is given that (x – y)(dx +dy) = dx – dy
⇒ (x –y + 1)dy = (1- x + y)dx
----------------(1)
Let x – y = t
Now, let us substitute the value of x-y and in equation (1), we get,
-------(2)
On integrating both side, we get,
t + log|t| = 2x + C
⇒ ( x – y ) + log |x – y| = 2x + C
⇒ log|x – y| = x + y + C --------(3)
Now, y = -1 at x = 0
Then, equation (3), we get,
log 1 = 0 -1 + C
⇒ C = 1
Substituting C = 1in equation (3), we get,
log|x – y| = x + y + 1
Therefore, a particular solution of the given differential equation is log|x – y| = x + y + 1.
Solve the differential equation
It is given that
This is equation in the form of (where, p = and Q = )
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
Find a particular solution of the differential equation (x ≠ 0), given that y = 0 when
It is given that
This is equation in the form of (where, p = cotx and Q = 4xcosecx)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
-----------(1)
Now, y = 0 at x =
Therefore, equation (1), we get,
0 =
⇒ C =
Now, substituting C = in equation (1), we get,
ysinx =
Therefore, the required particular solution of the given differential equation is
ysinx =
Find a particular solution of the differential equation , given that y = 0 when x = 0.
It is given that
On integrating both sides, we get,
----------------(1)
Let
⇒ eydt = -dt
Substituting value in equation (1), we get,
⇒ -log|t| = log|C(x+1)|
⇒ -log|2 – ey| = log|C(x + 1)|
------------------(2)
Now, at x = 0 and y = 0, equation (2) becomes,
⇒ C = 1
Now, substituting the value of C I equation (2), we get,
Therefore, the required particular solution of the given differential equation is
The population of a village increases continuously at the rate proportional to the number of its inhabitants present at any time. If the population of the village was 20, 000 in 1999 and 25000 in the year 2004, what will be the population of the village in 2009?
Let the population at any instant (t) be y.
Now it is given that the rate of increase of population is proportional to the number of inhabitants at any instant.
Now, integrating both sides, we get,
log y = kt + C ------(1)
According to given conditions,
In the year 1999, t = 0 and y = 20000
⇒ log20000 = C ----(2)
Also, in the year 2004, t = 5 and y = 25000
⇒ log 25000 = k.5 + C
⇒ log 25000 = 5k + log 20000
--------(3)
Also, in the year 2009, t = 10
Now, substituting the values of t, k and c in equation (1), we get
logy =
⇒ y = 31250
Therefore, the population of the village in 2009 will be 31250.
The general solution of the differential equation is
A. xy = C
B. x = Cy2
C. y = Cx
D. y = Cx2
It is given that
Integrating both sides, we get,
log|x| - log|y| = log k
⇒
⇒
⇒
⇒ y = Cx where C =
The general solution of a differential equation of the type is
A.
B.
C.
D.
The integrating factor of the given differential equation
is
Thus, the general solution of the differential equation is given by,
The general solution of the differential equation ex dy + (y ex + 2x) dx = 0 is
A. x ey + x2 = C
B. x ey + y2 = C
C. y ex + x2 = C
D. y ey + x2 = C
It is given that exdy + (yex + 2x) dx = 0
This is equation in the form of (where, p = 1 and Q = -2xe-x)
Now, I.F. =
Thus, the solution of the given differential equation is given by the relation:
y(I.F.) =
⇒ yex = -x2 + C
⇒ yex + x2 = C