Chapter 20: Differential Equations (ODE)—Basics (Set-1)

Which statement best defines a differential equation

A Equation with limits
B Equation with derivatives
C Equation with vectors
D Equation with matrices

In an ODE, the dependent variable usually depends on

A Only constants
B Two independent variables
C No independent variable
D One independent variable

What is the order offracd3ydx3+y=0fracd3ydx3+y=0

A 2
B 1
C 3
D 0

Order ofleft(fracdydxright)2+y=0left(fracdydxright)2+y=0 is

A 2
B 1
C Not defined
D 0

Degree is defined only when the equation is

A Polynomial in derivatives
B Separable only
C Linear in xx
D Free of constants

Degree ofleft(fracdydxright)4+x=0left(fracdydxright)4+x=0

A 2
B 1
C 3
D 4

Degree offracd2ydx2+left(fracdydxright)3=0fracd2ydx2+left(fracdydxright)3=0

A 2
B 1
C 5
D 3

Order of (y′′)2+y=0(y′′)2+y=0

A 4
B 1
C 2
D 3

Degree of (y′′)2+y=0(y′′)2+y=0

A Not defined
B 1
C 3
D 2

Which is a first-order differential equation

A y′+y=0y′+y=0
B y′′′+y=0y′′′+y=0
C (y′′)2+y=0(y′′)2+y=0
D y′′+y=0y′′+y=0

Which equation is nonlinear

A y′+2y=xy′+2y=x
B y′+xy=0y′+xy=0
C (y′)2+y=0(y′)2+y=0
D y′+y=sinxy′+y=sinx

Which is a linear first-order ODE form

A (y′)2+P(x)y=0(y′)2+P(x)y=0
B y′+P(x)y=Q(x)y′+P(x)y=Q(x)
C yy′+P(x)=0yy′+P(x)=0
D sin(y′)+y=0sin(y′)+y=0

A solution containing arbitrary constants is called

A Particular solution
B Singular point
C Exact form
D General solution

A solution satisfying given conditions is called

A Complementary set
B Particular solution
C Homogeneous form
D Degree solution

For first-order ODE, general solution has constants

A 1
B 2
C 0
D 3

For second-order ODE, general solution has constants

A 1
B 3
C 4
D 2

What does an initial condition usually specify

A Domain limits
B Highest degree
C Value at a point
D Slope field only

Which is an initial value problem example

A y′+y=0y′+y=0 only
B y′+y=0,y(0)=2y′+y=0,y(0)=2
C y′′+y=0y′′+y=0 only
D y′=xy′=x only

A boundary value problem gives conditions at

A No points
B One point only
C Random points
D Two points

Which indicates an ODE, not a PDE

A Multiple partial derivatives
B partial2y/partialxpartialypartial2y/partialxpartialy
C Only dy/dxdy/dx
D partialy/partialxpartialy/partialx

Homogeneous DE in x,yx,y means RHS is

A Function of xyxy
B Function of y/xy/x
C Function of x+yx+y
D Constant only

Standard substitution for homogeneous DE is

A y=v/xy=v/x
B y=v+xy=v+x
C x=vyx=vy
D y=vxy=vx

If y=vxy=vx, then dy/dxdy/dx equals

A v+x,dv/dxv+x,dv/dx
B v/x+dv/dxv/x+dv/dx
C x+v,dv/dxx+v,dv/dx
D v−x,dv/dxv−x,dv/dx

A separable equation can be written as

A y′′+y=0y′′+y=0
B Mdx+Ndy=0Mdx+Ndy=0 always
C f(y)dy=g(x)dxf(y)dy=g(x)dx
D y′+Py=Qy2y′+Py=Qy2 only

In y′+P(x)y=Q(x)y′+P(x)y=Q(x), integrating factor is

A intQ(x)dxintQ(x)dx
B eintP(x)dxeintP(x)dx
C eintQ(x)dxeintQ(x)dx
D intP(x)dxintP(x)dx

Main use of integrating factor is to make LHS

A Constant slope
B Quadratic form
C Separable always
D Exact derivative

Exact equation has standard form

A dy/dx=F(y/x)dy/dx=F(y/x)
B y′+Py=Qy′+Py=Q
C Mdx+Ndy=0Mdx+Ndy=0
D f(y)dy=g(x)dxf(y)dy=g(x)dx

Exactness condition is

A McdotN=1McdotN=1
B partialM/partialy=partialN/partialxpartialM/partialy=partialN/partialx
C partialM/partialx=partialN/partialypartialM/partialx=partialN/partialy
D M=NM=N

If equation is exact, solution is

A phi(x,y)=Cphi(x,y)=C
B y=mx+cy=mx+c
C M=N=CM=N=C
D y=Cxy=Cx

In exact method,phi(x,y)phi(x,y) is called

A Trial solution
B Auxiliary curve
C Degree function
D Potential function

Which indicates equation may need integrating factor

A Degree undefined
B Always separable
C Not exact initially
D Order zero

Integrating factor for linear ODE depends on

A Both x,yx,y
B P(x)P(x) only
C yy only
D Q(x)Q(x) only

If dy/dx=f(x)dy/dx=f(x), then yy equals

A f(x)+Cf(x)+C
B 1/f(x)+C1/f(x)+C
C intf(y)dyintf(y)dy
D intf(x)dx+Cintf(x)dx+C

If dy/dx=g(y)dy/dx=g(y), method is

A Separate variables
B Integrating factor
C Exactness test
D Variation method

A homogeneous linear ODE has Q(x)Q(x) as

A Polynomial only
B Exponential only
C 0
D Constant

In y′+P(x)y=0y′+P(x)y=0, solution form is

A y=C+intPdxy=C+intPdx
B y=Ce−intPdxy=Ce−intPdx
C y=CeintQdxy=CeintQdx
D y=Px+Cy=Px+C

Bernoulli equation basic form is

A Mdx+Ndy=0Mdx+Ndy=0
B dy/dx=F(y/x)dy/dx=F(y/x)
C y′+Py=Qy′+Py=Q
D y′+Py=Qyny′+Py=Qyn

In Bernoulli, substitution usually is

A v=ynv=yn
B v=xyv=xy
C v=y1−nv=y1−n
D v=y/xv=y/x

General solution represents a

A Single slope
B Family of curves
C Single point
D Only constant

A particular solution is obtained by

A Differentiating twice
B Setting x=0x=0
C Removing derivatives
D Applying conditions

To verify a proposed solution, you should

A Substitute into DE
B Change independent variable
C Differentiate only once
D Compare degrees only

An implicit solution is usually written as

A x=g(y)x=g(y) only
B F(x,y)=CF(x,y)=C
C y=mx+cy=mx+c
D y=f(x)y=f(x) always

An explicit solution is written as

A F(x,y)=CF(x,y)=C
B Mdx+Ndy=0Mdx+Ndy=0
C y′′=0y′′=0
D y=f(x)y=f(x)

Which is a separable differential equation

A Mdx+Ndy=0Mdx+Ndy=0
B y′′+y=0y′′+y=0
C dy/dx=xydy/dx=xy
D y′+xy=1y′+xy=1

Equation dy/dx=x/ydy/dx=x/y is

A Not solvable
B Separable
C Exact always
D Second order

Equation dy/dx=(x+y)/xdy/dx=(x+y)/x is

A Homogeneous type
B Exact type
C Second order
D Not an ODE

Exact equation corresponds to differential of

A Two constants
B Linear factor
C Only derivative
D Single function

If integrating factor depends only on xx, it ismu(x)mu(x) where

A mu(x)=sinymu(x)=siny
B mu(x)=x+ymu(x)=x+y
C mu(x)Mdx+mu(x)Ndymu(x)Mdx+mu(x)Ndy exact
D mu(x)=y/xmu(x)=y/x

Growth model differential equation is commonly

A dy/dt=k+ydy/dt=k+y
B dy/dt=kydy/dt=ky
C dy/dt=ktdy/dt=kt
D dy/dt=y/kdy/dt=y/k

A slope field represents

A Exactness condition
B Degree of equation
C Direction of solutions
D Number of constants
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