Chapter 19: Integration and Applications (Set-3)

A function f(x)f(x) satisfies f′(x)=2x(1+x2)4f′(x)=2x(1+x2)4. What is ∫2x(1+x2)4 dx∫2x(1+x2)4dx?

A (1+x2)55+C5(1+x2)5+C
B (1+x2)5+C(1+x2)5+C
C 2x(1+x2)4+C2x(1+x2)4+C
D (1+x2)44+C4(1+x2)4+C

When is integration by parts most directly useful?

A Sum of powers
B Pure rational form
C Product with log
D Simple chain form

Evaluate ∫xex dx∫xexdx (indefinite).

A xex+ex+Cxex+ex+C
B ex/x+Cex/x+C
C x2ex+Cx2ex+C
D xex−ex+Cxex−ex+C

For ∫3×21+x3 dx∫1+x33x2dx, best first step is

A Use partial fractions
B Substitute u=1+x3u=1+x3
C Use by parts
D Use symmetry rule

Compute ∫1×2−4 dx∫x2−41dx using partial fractions.

A 12ln⁡∣x2−4∣+C21ln⁡∣x2−4∣+C
B ln⁡∣x−2∣+ln⁡∣x+2∣+Cln⁡∣x−2∣+ln⁡∣x+2∣+C
C 14ln⁡∣x−2x+2∣+C41lnx+2x−2+C
D 14ln⁡∣x2−4∣+C41ln⁡∣x2−4∣+C

Evaluate ∫x1−x2 dx∫1−x2xdx.

A 1−x2+C1−x2+C
B sin⁡−1x+Csin−1x+C
C tan⁡−1x+Ctan−1x+C
D −1−x2+C−1−x2+C

If ff is continuous, then ddx(∫2xf(t) dt)dxd(∫2xf(t)dt) equals

A f(2)f(2)
B ∫2xf(t)dt∫2xf(t)dt
C f(x)f(x)
D f′(x)f′(x)

Evaluate ∫0πsin⁡x dx∫0πsinxdx.

A 00
B 22
C ππ
D 11

Using symmetry, ∫−aax2 dx∫−aax2dx equals

A 00
B ∫0ax2dx∫0ax2dx
C −2∫0ax2dx−2∫0ax2dx
D 2∫0ax2dx2∫0ax2dx

Compute ∫01(2x+1) dx∫01(2x+1)dx.

A 11
B 33
C 22
D 3223

If F′(x)=f(x)F′(x)=f(x), then ∫abf(x) dx∫abf(x)dx equals

A F(b)−F(a)F(b)−F(a)
B F(a)−F(b)F(a)−F(b)
C F(a)+F(b)F(a)+F(b)
D F′(b)−F′(a)F′(b)−F′(a)

For H(x)=∫1x2f(t) dtH(x)=∫1x2f(t)dt, derivative H′(x)H′(x) equals

A f(x)f(x)
B f(x2)f(x2)
C 2x f(x)2xf(x)
D 2x f(x2)2xf(x2)

Which integral equals ln⁡∣x∣−1x+Cln∣x∣−x1+C?

A ∫(1x+1×2)dx∫(x1+x21)dx
B ∫(1x+x2)dx∫(x1+x2)dx
C ∫(1x−1×2)dx∫(x1−x21)dx
D ∫(1x−x2)dx∫(x1−x2)dx

Compute ∫tan⁡xsec⁡2x dx∫tanxsec2xdx.

A tan⁡2×2+C2tan2x+C
B ln⁡∣sec⁡x∣+Cln∣secx∣+C
C tan⁡x+Ctanx+C
D sec⁡x+Csecx+C

Evaluate ∫11+x2 dx∫1+x21dx.

A sin⁡−1x+Csin−1x+C
B ln⁡∣x∣+Cln⁡∣x∣+C
C tan⁡−1x+Ctan−1x+C
D 1x+Cx1+C

For ∫02∣x−1∣ dx∫02∣x−1∣dx, correct approach is

A Use symmetry only
B Split at x=1x=1
C Use by parts
D Use partial fractions

Area between y=xy=x and y=x2y=x2 from 00 to 11 is

A ∫01(x2−x)dx∫01(x2−x)dx
B ∫01(x+x2)dx∫01(x+x2)dx
C ∫01(x2/x)dx∫01(x2/x)dx
D ∫01(x−x2)dx∫01(x−x2)dx

Compute area between y=xy=x and y=x2y=x2 on [0,1][0,1].

A 1331
B 1221
C 1661
D 2332

For volume by disks about x-axis, the basic form is

A ∫ydx∫ydx
B π∫y2dxπ∫y2dx
C π∫ydxπ∫ydx
D ∫y2dx∫y2dx

A probability density p(x)p(x) must satisfy which basic condition?

A ∫p=0∫p=0
B p<0p<0 always
C pp periodic
D ∫p=1∫p=1

Which integral gives arc length idea (intro) for y=f(x)y=f(x)?

A ∫1+(f′)2 dx∫1+(f′)2dx
B ∫(1+f′) dx∫(1+f′)dx
C ∫(f′)2 dx∫(f′)2dx
D ∫1+f dx∫1+fdx

If f(x)≥g(x)f(x)≥g(x) on [a,b][a,b], then area between them is

A ∫ab(g−f)dx∫ab(g−f)dx
B ∫ab(fg)dx∫ab(fg)dx
C ∫ab(f−g)dx∫ab(f−g)dx
D ∫ab(f+g)dx∫ab(f+g)dx

Evaluate ∫01×2 dx∫01x2dx.

A 1221
B 1441
C 2332
D 1331

A correct symmetry shortcut is ∫−22(x3+1) dx∫−22(x3+1)dx equals

A ∫−22x3dx∫−22x3dx
B ∫−221dx∫−221dx
C 00
D 2∫02x3dx2∫02x3dx

Compute ∫−22(x3+1) dx∫−22(x3+1)dx.

A 00
B 88
C 44
D −4−4

Which integral form matches Leibniz rule (basic) idea?

A ddx∫a(x)b(x)f(t)dtdxd∫a(x)b(x)f(t)dt
B ddx∫abf(x)dxdxd∫abf(x)dx
C ∫abf′(t)dt∫abf′(t)dt
D ∫abf(x)2dx∫abf(x)2dx

If J(x)=∫0xsin⁡(t2) dtJ(x)=∫0xsin(t2)dt, then J′(x)J′(x) is

A 2xsin⁡x2xsinx
B cos⁡(x2)cos(x2)
C sin⁡2xsin2x
D sin⁡(x2)sin(x2)

Which evaluation technique is correct for ∫02(x−1)dx∫02(x−1)dx?

A Use symmetry only
B Use by-parts
C Use antiderivative
D Use partial fractions

Compute ∫02(x−1) dx∫02(x−1)dx.

A 11
B 00
C 22
D −1−1

If f(x)≥0f(x)≥0, then which is always true?

A ∫abf≤0∫abf≤0
B ∫abf=0∫abf=0
C ∫abf=b−a∫abf=b−a
D ∫abf≥0∫abf≥0

For ∫0πcos⁡x dx∫0πcosxdx, the value is

A 22
B ππ
C 00
D −2−2

Compute ∫1a2−x2 dx∫a2−x21dx for a>0a>0.

A sin⁡−1(x/a)+Csin−1(x/a)+C
B tan⁡−1(x/a)+Ctan−1(x/a)+C
C ln⁡∣x∣+Cln⁡∣x∣+C
D sec⁡−1(x/a)+Csec−1(x/a)+C

Which is correct for ∫e2x dx∫e2xdx?

A 2e2x+C2e2x+C
B ex2+Cex2+C
C ln⁡∣2x∣+Cln⁡∣2x∣+C
D 12e2x+C21e2x+C

Which is correct for ∫ln⁡x dx∫lnxdx (for x>0x>0)?

A (ln⁡x)2+C(lnx)2+C
B ln⁡∣x∣/x+Cln∣x∣/x+C
C xln⁡x−x+Cxlnx−x+C
D xln⁡x+Cxlnx+C

For improper integral ∫1∞1xp dx∫1∞xp1dx, it converges when

A p>1p>1
B p=1p=1
C p<1p<1
D p=0p=0

The integral ∫011xpdx∫01xp1dx converges when

A p=1p=1
B p>1p>1
C p<1p<1
D p=0p=0

A correct “change of variable” step in definite integral is

A Keep old bounds
B Ignore bounds
C Swap bounds always
D Change bounds too

Which is a correct polar area preview statement?

A Uses derivative only
B Sector area formula
C Needs partial fractions
D Always zero area

Compute ∫0π/2sin⁡x dx∫0π/2sinxdx.

A 00
B 1221
C 11
D 22

For area in first quadrant bounded by y=xy=x, x-axis, and x=4x=4, area is

A ∫04x dx∫04xdx
B ∫041xdx∫04x1dx
C ∫04ln⁡x dx∫04lnxdx
D ∫04x dx∫04xdx

Which best describes “surface area of revolution” (intro)?

A Integrate strip areas
B Differentiate curve
C Use symmetry only
D Use factoring only

A correct basic idea for “moment of inertia” (intro) is

A ∫r dm∫rdm
B ∫r2dm∫r2dm
C ∫dm/r2∫dm/r2
D ∫r3dm∫r3dm

Which method often simplifies ∫dxx2−a2∫x2−a2dx (intro)?

A Partial fractions
B By parts
C Symmetry rule
D Trig substitution

Which inequality statement is correct for integrals?

A If f≥gf≥g, then ∫f=∫g∫f=∫g
B If f≥gf≥g, then ∫f≤∫g∫f≤∫g
C If f≥gf≥g, then ∫f≥∫g∫f≥∫g
D If f≥gf≥g, then ∫f=0∫f=0

Compute ∫1x(x+1) dx∫x(x+1)1dx.

A ln⁡∣x∣+ln⁡∣x+1∣+Cln⁡∣x∣+ln⁡∣x+1∣+C
B ln⁡∣x∣−ln⁡∣x+1∣+Cln⁡∣x∣−ln∣x+1∣+C
C ln⁡∣x+1∣+Cln⁡∣x+1∣+C
D ln⁡∣x∣+Cln⁡∣x∣+C

A correct standard integral is ∫1a2+x2dx∫a2+x21dx equals

A tan⁡−1(x/a)+Ctan−1(x/a)+C
B sin⁡−1(x/a)+Csin−1(x/a)+C
C ln⁡∣x+a2+x2∣+Cln⁡∣x+a2+x2∣+C
D ln⁡∣x∣+Cln⁡∣x∣+C

Integral test for series (intro) connects series to

A Matrix products
B Trig identities
C Vector spaces
D Improper integrals

Solve y′=2xy′=2x using integration (basic). General solution is

A y=x2+Cy=x2+C
B y=2x+Cy=2x+C
C y=x+Cy=x+C
D y=2×2+Cy=2×2+C

A correct “splitting interval” trick is

A ∫abf=∫acf−∫cbf∫abf=∫acf−∫cbf
B ∫abf=∫cbf∫abf=∫cbf
C ∫abf=∫acf+∫cbf∫abf=∫acf+∫cbf
D ∫abf=∫abf(c)∫abf=∫abf(c)

Which is correct for ∫01(1−x)dx∫01(1−x)dx?

A 11
B 00
C 1331
D 1221
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