> Evaluate the integral. x - 2x? + 2x – 5 dx x* + 4x² + 3
> Evaluate the integral. x + 4 dx J x? + 2x + 5
> Evaluate the integral. x3 + 6х — 2 dx x* + 6x²
> Evaluate the integral. x' + 4x + 3 dx x* + 5x? + 4
> Evaluate the integral. x? + x + 1 dx (x² + 1)²
> Evaluate the integral. 4x dx x² + x + 1 .3 x' +
> Evaluate the integral. x? - x + 6 dx x' + 3x
> Use a power series to approximate the definite integral to six decimal places. ro.3 dx 1+ x*
> Evaluate the integral. 10 dx (x – 1)(x² + 9) .2
> Evaluate the integral. x* + 9x? + x + 2 dx x² + 9
> Evaluate the integral. dt (1? – 1)?
> Evaluate the integral. x(3 — 5х) dx J (3x – 1)(x – 1)²
> Evaluate the integral. x? 1 + x + dx Jo (x + 1)°(x + 2)
> Evaluate the integral. Зx2 + 6х + 2 dx х? + 3х + 2
> Evaluate the integral. 4y? — Ту — 12 dy Л у(у + 2)(у — 3)
> Evaluate the integral. x' + 4x? + x - 1 dx x' + x?
> Evaluate the integral. x - 4x + 1 · dx 1 x² – 3x + 2
> Evaluate the integral. 1 (x + a)(x + b)
> Use a power series to approximate the definite integral to six decimal places. c0.2 x In(1 + x²) dx
> Evaluate the integral. x - 4 dx -o?? - 5x + 6
> Evaluate the integral. 2 dx Jo 2x + 3x + 1
> Evaluate the integral. y dy (y + 4)(2y – 1)
> Evaluate the integral. 5х + 1 - dx (2х + 1)(х — 1)
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. 16 + 1 (a) 16 + t³ x* + 1 (b) (x² – x)(x* + 2x² + 1)
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. (a) x? – 4 (b) (x² – x + 1)(x² + 2)²
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. x² – 1 x* – 2x + x? + 2x – 1 (a) (b) x³ + x + x x² – 2x + 1
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. x' +1 (b) x³ – 3x² + 2x 1 (a) x? + x*
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. х — 6 (a) x² + x – 6 x? (b) x? + x + 6
> Write out the form of the partial fraction decomposition of the function (as in Example 7). Do not determine the numerical values of the coefficients. 4 + x 1- x (a) (1 + 2х)(3 — х) (b) x' + x*
> Use a power series to approximate the definite integral to six decimal places. 1/2 " arctan(x/2) dx
> The functions y = ex2 and y = x2 ex2 don’t have elementary antiderivatives, but / does. Evaluate /
> Evaluate the integral. sin x cos x sin'x + cos“x
> Evaluate the integral. – sin x dx
> Evaluate the integral. sec x cos 2x sin x + sec x
> Evaluate the integral. Sx sin'x cos x dx
> Evaluate the integral. 1+ sin x dx SI 1- sin x
> Evaluate the integral. xe* dx /1 + e*
> Evaluate the integral. dx Vx² + 1
> Evaluate the integral. dx х In x — х
> Use a power series to approximate the definite integral to six decimal places. r0.3 Jo 1+ x3 dx
> Evaluate the integral. :+ arcsin. dx VI - x² 1 –
> Evaluate the integral. In(x + 1) ax x?
> Evaluate the integral. e 2x dx 1x 1+ e*
> Evaluate the integral. 1 dx 1+ 2e* — е *
> Evaluate the integral. 1 + x² dx 2
> Evaluate the integral. x? dx хв + 3x3 + 2
> Evaluate the integral. 1 dx /x + 1 + Vx
> Evaluate the integral. m/3_In(tan x) – dx Ja/4 sin x cos x
> Evaluate the integral. sin 2x dx J1+ cos“x
> Evaluate the indefinite integral as a power series. What is the radius of convergence? tan x dx
> Evaluate the integral. dx
> Evaluate the integral. de 1 + cos?e
> Evaluate the integral. de 1 + cos 0
> Evaluate the integral. dx J x*/4x? – 1
> Evaluate the integral. dx x* - 16
> Evaluate the integral. x In x dx /x² 1
> Evaluate the integral. fxk + c dx
> Evaluate the integral. dx x^x + x^
> Evaluate the integral. dx x + x/r
> Evaluate the integral. | (x + sin x)² dx
> Evaluate the indefinite integral as a power series. What is the radius of convergence? |x? In(1 + x) dx
> Evaluate the integral. |x' sinh mx dx х* si
> Evaluate the integral. dx Jx(x* + 1)
> Evaluate the integral. 1 x/4x2 + 1
> Evaluate the integral. 1 dx J x?V4x + 1
> Evaluate the integral. 1 dx J x/4x + 1
> Evaluate the integral. x/2 - VI - x² dx
> Evaluate the integral. Sx(x – 1) *dx
> Evaluate the integral. (x – 1)e* dx .2 x
> Evaluate the integral. fx'e "dx
> Evaluate the integral. SVi+e" dx
> Evaluate the indefinite integral as a power series. What is the radius of convergence? i - 1+ t
> Evaluate the integral. dx 1 + x³
> Evaluate the integral. tan'x dx
> Evaluate the integral. |O tan'o do
> Evaluate the integral. | sin 6x cos 3x dx
> Evaluate the integral. sec 0 tan 0 o - J sec'o – sec 0
> Evaluate the integral. /3 sin 0 cot 0 do Jw/6 sec 0
> Evaluate the integral. 1 + sin x dx 1 + cos x
> Evaluate the integral. 12 1 + 4 cot x dx Ja/4 4 - cot x
> Evaluate the integral. |V3 – 2x – x² dx
> Evaluate the integral. 3/3 3 dx 2
> Evaluate the indefinite integral as a power series. What is the radius of convergence? dt
> Evaluate the integral. 1 + x dx
> Evaluate the integral. S,le - 1|dx
> Evaluate the integral. S In(x + vx? – T) dx
> Evaluate the integral. S sin Jat dt
> Evaluate the integral. dx J 1+ e*
> Evaluate the integral. 3x² + 1 dx Jo x³ + x? + x +1
> Evaluate the integral. + tan x)? sec x dx
> Evaluate the integral. + dx
> Evaluate the integral. In x -dx x/1 + (In x)²
> Evaluate the integral. | arctan /x dx
> Find a power series representation for f, and graph f and several partial sums sn(x) on the same screen. What happens as n increases? f(x) = tan (2x)
> (a) Approximate f by a Taylor polynomial with degree n at the number a. (b) Use Taylor’s Inequality to estimate the accuracy of the approximation / when x lies in the given interval. (c) Check your result in part (b) by graphing / S
> Evaluate the integral. t cos?t dt Jo CoS
> Evaluate the integral. x? dx VI - x2
> Evaluate the integral. X sec x tan x dx
> Evaluate the integral. In(1 + x²) dx
> Evaluate the integral. ( sin't cos't dt