Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 4 as we have and the degree is the highest power to which a derivative is raised. But when we open the Cos x series, we get This leads to an undefined power on the highest derivative. Therefore the deg9ee of this function becomes undefined.
So the answer is 4, not defined.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 2, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 2, 2.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 2, 2.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 3 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 3, 2.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 2, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 1 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 1. Also, the equation has to be a polynomial, but here the exponential function does not take any derivative with this. Hence it is a polynomial.
So the answer is 1, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. But here when we open the series of as . Also, the equation has to be polynomial. Therefore the degree is not defined. Also, the equation has to be a polynomial, but opening the exponential function will give undefined power to the highest derivative, so the degree of this function is not defined.
So the answer is 2, not defined .
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 1 as we have and the degree is the highest power to which a derivative is raised. But when we open Sin x as . Also, the equation has to be polynomial, and opening thus, Sin function will lead to an undefined power of the highest derivative. Therefore the degree is not defined.
So the answer is 1, not defined.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 1. Because the logarithm function is not at any derivative, so it doesn’t destroy the polynomial.Hence degree is 1
So the answer is 2, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 1 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 3. Because the Sine function is not at any derivative, so it doesn’t destroy the polynomial.Hence the degree is 3.
So the answer is 1, 3.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 3 as we have and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 3, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 1 as we have
and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 1, 2.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So the order comes out to be 2/3 as we have
and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 2/3, 2.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So, the order comes out to be 1 as we have
and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 1, 1.
Write order and degree (if defined)of each of the following differential equations:
The order of a differential equation is the order of the highest derivative involved in the equation. So, the order comes out to be 3 as we have
and the degree is the highest power to which a derivative is raised. So the power at this order is 2.
So the answer is 3, 2.
Write order and degree (if defined)of each of the following differential equations:
(3x + 5y)dy - 4x2 dx = 0
The order of a differential equation is the order of the highest derivative involved in the equation. So, the order comes out to be 1 as we have (3x + 5y)dy - 4x2 dx = 0
and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 1, 1.
Write order and degree (if defined)of each of the following differential equations:
Given:
Solving, we get,
Now,
The order of a differential equation is the order of the highest derivative involved in the equation. So, the order comes out to be 2 as we have,
and the degree is the highest power to which a derivative is raised. So the power at this order is 1.
So the answer is 2, 1.
Verify that x2 = 2y2log y is a solution of the differential equation (x2 + y2) - xy = 0.
Given
On differentiating both sides with respect to x, we get
Multiply both sides with y
We know, . So replace with in the above equation.
Conclusion: Therefore is the solution of
Verify that x2 = 2y2log y is a solution of the differential equation (x2 + y2) - xy = 0.
Given
On differentiating both sides with respect to x, we get
Multiply both sides with y
We know, . So replace with in the above equation.
Conclusion: Therefore is the solution of
Verify that y = ex cos bx is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
This is not a solution
Conclusion: Therefore, y = ex cos bx is not the solution of
Verify that y = ex cos bx is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
This is not a solution
Conclusion: Therefore, y = ex cos bx is not the solution of
Verify that y = is a solution of the differential equation (1 - x2)
Given
On differentiating with x, we get
On differentiating again with x, we get
We want to find
= 0
Therefore, is the solution of
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation (1 - x2)
Given
On differentiating with x, we get
On differentiating again with x, we get
We want to find
= 0
Therefore, is the solution of
Conclusion: Therefore, is the solution of
Verify that y = (a + bx) e2x is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = (a + bx) e2x is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = ex(A cos x + B sin x) is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = ex(A cos x + B sin x) is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = A cos 2x - B sin 2x is the general solution of the differential equation = 0.
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = A cos 2x - B sin 2x is the general solution of the differential equation = 0.
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = ae2x + be - x is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion : Therefore, is the solution of
Verify that y = ae2x + be - x is the general solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion : Therefore, is the solution of
Show that y = ex(A cos x + B sin x) is the solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Show that y = ex(A cos x + B sin x) is the solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y2 = 4a(x + a) is a solution of the differential equation
Given,
On differentiating with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y2 = 4a(x + a) is a solution of the differential equation
Given,
On differentiating with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation (1 + x2) + (2x - 1) = 0
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
Conclusion: Therefore, is not the solution of
Verify that y = is a solution of the differential equation (1 + x2) + (2x - 1) = 0
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
Conclusion: Therefore, is not the solution of
Verify that y = is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = e- x + Ax + B is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 1
Conclusion: Therefore, is the solution of
Verify that y = e- x + Ax + B is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 1
Conclusion: Therefore, is the solution of
Verify that Ax2 + By2 = 1 is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that Ax2 + By2 = 1 is a solution of the differential equation
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation (1 + x2) + (1 + y2) = 0.
Given
On differentiating with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = is a solution of the differential equation (1 + x2) + (1 + y2) = 0.
Given
On differentiating with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = log (x + satisfies the differential equation.
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
Conclusion: Therefore, is not the solution of
Verify that y = log (x + satisfies the differential equation.
Given
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
Conclusion: Therefore, is not the solution of
Verify that y = e - 3x is a solution of the differential equation
Given,
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Verify that y = e - 3x is a solution of the differential equation
Given,
On differentiating with x, we get
On differentiating again with x, we get
Now let’s see what is the value of
= 0
Conclusion: Therefore, is the solution of
Form the differential equation of the family of straight lines y=mx+c, where m and c are arbitrary constants.
The equation of a straight line is represented as,
Y = mx + c
Differentiating the above equation with respect to x,
Differentiating the above equation with respect to x,
This is the differential equation of the family of straight lines y=mx+c, where m and c are arbitrary constants
Form the differential equation of the family of concentric circles x2+y2=a2, where a>0 and a is a parameter.
Now, in the general equation of of the family of concentric circles x2+y2=a2, where a>0, ‘a’ represents the radius of the circle and is an arbitrary constant.
The given equation represents a family of concentric circles centered at the origin.
x2+y2=a2
Differentiating the above equation with respect to x on both sides, we have,
(As a>0, derivative of a with respect to x is 0.)
Form the differential equation of the family of curves, y=a sin (bx+c), Where a and c are parameters.
Equation of the family of curves, y=a sin (bx+c), Where a and c are parameters.
Differentiating the above equation with respect to x on both sides, we have,
(1)
(Substituting equation 1 in this equation)
This is the required differential equation.
Form the differential equation of the family of curves x=A cos nt+ Bsin nt, where A and B are arbitrary constants.
Equation of the family of curves, x=A cos nt+ Bsin nt, where A and B are arbitrary constants.
Differentiating the above equation with respect to t on both sides, we have,
(1)
(Substituting equation 1 in this equation)
This is the required differential equation.
Form the differential equation of the family of curves y=aebx, where a and b are arbitrary constants.
Equation of the family of curves, y=aebx, where a and b are arbitrary constants.
Differentiating the above equation with respect to x on both sides, we have,
(1)
(2)
(Multiplying both sides of the equation by y)
(Substituting equation 2 in this equation)
This is the required differential equation.
Form the differential equation of the family of curves y2=m(a2-x2), where a and m are parameters.
Equation of the family of curves, y2=m(a2-x2), where a and m are parameters.
Differentiating the above equation with respect to x on both sides, we have,
(1)
Differentiating the above equation with respect to x on both sides,
(2)
From equations (1) and (2),
This is the required differential equation.
Form the differential equation of the family of curves given by (x-a)2+2y2=a2, where a is an arbitrary constant.
Equation of the family of curves, (x-a)2+2y2=a2, where a is an arbitrary constant.
(1)
Differentiating the above equation with respect to x on both sides, we have,
(Substituting 2ax from equation 1)
This is the required differential equation.
Form the differential equation of the family of curves given by x2+y2-2ay=a2, where a is an arbitrary constant.
Equation of the family of curves, x2+y2-2ay=a2, where a is an arbitrary constant.
(1)
Differentiating the above equation with respect to x on both sides, we have,
(Substituting 2ax from equation 1)
This is the required differential equation.
Form the differential equation of the family of all circles touching the y-axis at the origin.
Equation of the family of all circles touching the y-axis at the origin can be represented by
(x-a)2+y2=a2, where a is an arbitrary constants.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
Rearranging the above equation
This is the required differential equation.
From the differential equation of the family of circles having centers on y-axis and radius 2 units.
Equation of the family of circles having centers on y-axis and radius 2 units can be represented by
(x)2+(y – a)2= 4, where a is an arbitrary constant.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
Rearranging the above equation
This is the required differential equation.
Form the differential equation of the family of circles in the second quadrant and touching the coordinate axes
Equation of the family of circles in the second quadrant and touching the coordinate axes
can be represented by
(x – (-a))2+(y – a)2= a2, where a is an arbitrary constants.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
Rearranging the above equation
This is the required differential equation.
Form the differential equation of the family of circles having centers on the x-axis and radius unity.
Equation of the family of circles having centers on the x-axis and radius unity can be represented by
(x - a)2+(y)2= 1, where a is an arbitrary constants.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
This is the required differential equation.
Form the differential equation of the family of circles passing through the fixed point (a,0) and (-a,0), where a is the parameter.
Now, it is not necessary that the centre of the circle will lie on origin in this case. Hence let us assume the coordinates of the centre of the circle be (0, h). Here, h is an arbitrary constant.
Also, the radius as calculated by the Pythagoras theorem will be a2 + h2.
Hence, the equation of the family of circles passing through the fixed point (a,0) and (-a,0), where a is the parameter can be represented by
(x)2+(y – h)2= a2 + h2, where a is an arbitrary constants.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
This is the required differential equation.
Form the differential equation of the family of parabolas having a vertex at the origin and axis along positive y-axis.
Equation of the family of parabolas having a vertex at the origin and axis along positive y-axis can be represented by
(x)2 = 4ay, where a is an arbitrary constants.
(1)
Differentiating the above equation with respect to x on both sides, we have,
Substituting the value of a in equation (1)
This is the required differential equation.
Form the differential equation of the family of an ellipse having foci on the y-axis and centers at the origin.
Equation of the family of an ellipse having foci on the y-axis and centers at the origin can be represented by
(1)
Differentiating the above equation with respect to x on both sides, we have,
Again differentiating the above equation with respect to x on both sides, we have,
Rearranging the above equation
This is the required differential equation.
Form the differential equation of the family of hyperbolas having foci on the x-axis and centers at the origin.
Equation of the family of an ellipse having foci on the y-axis and centers at the origin can be represented by
(1)
Differentiating the above equation with respect to x on both sides, we have,
Again differentiating the above equation with respect to x on both sides, we have,
Rearranging the above equation
This is the required differential equation.