Respuesta :
Answer :
Q1. f'(x)=-20x+4. When x=11, this is f'(11)=-20×11+4=-220+4=-216.
Q2. Lim(x➝4) of x²+3x-1. The expression can be evaluated by direct substitution without constraints: 16+12-1=27.
Q3. The derivative is 7 for all values of x because the function is linear with a constant slope.
Q4. The function is piecewise. We need the conditions that apply when x is close to zero. We need to look at x approaching from the negative side and the positive side. If the limits are not the same the limit does not exist. So, when x<0 we use 7-x². When x is just less than zero, this left-hand limit is 7. When x>0 we use 10x+7. When x is just bigger than zero, this right-hand limit is 7. We are not interested in x=0, we are only interested in the left- and right-hand limits, which happen to be the same. So the limit is 7.
Q5. f'(x)=-3/x². f'(1)=-3.
Q6. In all limit questions, you can always ignore what happens when x=limit, because it’s the approaches that matter. So x➝2⁻ means look at the graph on the left of the limit. The horizontal line at y=4 means the left limit is 4. x➝2⁺ means look at the graph on the right of the limit. This is where y=-3, so the right limit is -3. The answer is 4 and -3 for left and right limits respectively.
Q7. First find left and right limits: x➝-1⁻: use x<-1: f(x)=x+1, so left limit is 0; x➝-1⁺: use x>-1: f(x)=1-x: so right limit is 1-(-1)=2. The left and right limits are different, so the limit does not exist.
Q8. 1/(x-7). When x=7, this quantity is not defined and this is a vertical asymptote. When x➝7⁻ we can use a value of x slightly less than 7 and see what happens. First try x=6.99, then 1/(x-7)=-100. Now try x=6.999, then we get -1000. So it’s getting larger in magnitude, and it’s negative. An infinitely large negative value is -∞. So the limit as x approaches 7 from the left is -∞.
Q9. Ignore the closed point at (3,7). For x➝3⁻, we are on the sloping line, so the limit is 1.5.
Q10. As x approaches zero the numerator approaches 1. The denominator gets smaller so its reciprocal gets larger, and it can be positive or negative depending on how we approach zero. So we can’t define the limit, so it doesn’t exist.
Q11. Derivative is -(-3/x²)=3/x². When x=-4, this is 3/16, because (-4)²=16.
Q12. x²-2➝-2 when x➝0.
Q13. (x²-16)/(x-4)=(x-4)(x+4)/(x-4)➝x+4 because the common factor x-4 cancels. Note that the quantity does not exist at precisely x=4 but in the limit it approaches x+4=8 when x=4. So the answer is 8 for the limit.
Q14. The derivative is constant -13 and is independent of t, so the instantaneous velocity is -13.
Q15. 1/(x-2)² is always positive, so it doesn’t matter whether we look at the left or right limits. The result as x➝2 is ∞, which is an undefinable quantity. x=2 is a vertical asymptote.
ANSWER TO QUESTION 1
The given function is [tex]f(x)=-10x^2+4x[/tex]. We want to find the derivative of this function at [tex]x=11[/tex].
The derivative of this function is given by,
[tex]f'(x)=-20x+4[/tex]
We now have to substitute [tex]x=11[/tex] in to [tex]f'(x)=-20x+4[/tex] to obtain,
[tex]f'(11)=-20(11)+4[/tex]
This implies that,
[tex]f'(11)=-220+4[/tex]
[tex]f'(11)=-216[/tex]
Ans: A
ANSWER TO Q2.
The given limit is [tex]\lim_{x \to 4}^{ x^2+3x-1}[/tex].
The function whose limit we are finding is a polynomial function. Since polynomial function are continuous everywhere, the limiting value is always equal to the functional value.
Thus, [tex]\lim_{x \to 4}^{ x^2+3x-1}=f(4)[/tex]
This implies that,
Thus, [tex]\lim_{x \to 4}^{ x^2+3x-1}=(4)^2+3(4)-1[/tex].
[tex]\lim_{x \to 4}^{ x^2+3x-1}=16+12-1[/tex]
[tex]\lim_{x \to 4}^{ x^2+3x-1}=27[/tex]
Ans: A.
ANSWER TO Q3
The given function is [tex]f(x)=7x+9[/tex].
We want to find the derivative of this function at [tex]x=6[/tex].
We must first of all differentiate this function to obtain,
[tex]f'(x)=7[/tex]
We can see that the derived function is constant, therefore value of [tex]x[/tex] will still give us [tex]7.[/tex]
This implies that,
[tex]f'(6)=7[/tex]
Ans: A
ANSWER TO Q4.
See attachment
ANSWER TO Q5.
The given function is [tex]f(x)=\frac{3}{x}[/tex].
To find the derivative of this function at,
[tex]x=1[/tex], we must first differentiate this function.
But let us rewrite the rational function as a power function so that it will be easier to differentiate using the power rule of differentiation.
That is,
[tex]f(x)=3x^{-1}[/tex].
We differentiate now to obtain,
[tex]f'(x)=-1(3x^{-1-1})[/tex]
This implies that,
[tex]f'(x)=-3x^{-2}[/tex]
[tex]f'(x)=\frac{-3}{x^2}[/tex]
At [tex]x=1[/tex]
[tex]f'(1)=\frac{-3}{(1)^2}[/tex]
[tex]f'(1)=-3[/tex]
Ans: A
ANSWER TO Q6
The graph that has been described in the question is shown in the diagram above,
We can see from the graph that as we approach [tex]x=2[/tex], from the left, the y-values are approaching [tex]4[/tex].
That is,
[tex]\lim_{x \to 2^{-}} f(x)=4[/tex]
Also as we approach [tex]x=2[/tex] from the right, the y-values are approaching [tex]-3[/tex].
That is,
[tex]\lim_{x \to 2^{+}} f(x)=-3[/tex].
Ans: D.
ANSWER TO Q7
The given piece-wise function is
[tex]\lim_{x \to -1} \left \{ {{x+1,if\:x\:<\:-1} \atop {1-x,if\:x\:\ge -1}} \right.[/tex]
Since [tex]x=-1 \in x\geq -1[/tex]
We evaluate the limit at [tex]x=-1[/tex] of [tex]f(x)=1-x[/tex].
Since this is a polynomial function, [tex]\lim_{x \to -1}f(x)= 1-x=f(-1)[/tex]
This implies that,
[tex]\lim_{x \to -1} f(x)=1-x=1--1[/tex]
[tex]\lim_{x \to -1} f(x)=1-x=1--1[/tex]
[tex]\lim_{x \to -1} f(x)=1-x=1+1[/tex]
[tex]\lim_{x \to -1} f(x)=1-x=2[/tex]
Ans: B.
ANSWER TO Q8
The given function is [tex]f(x)=\frac{1}{x-7}[/tex].
This is a rational function that is defined for all real values except,[tex]x-7=0[/tex]
Therefore the vertical asymptote is [tex]x=7[/tex]
We can see from the graph above that, as x approaches seven from the left, the function approaches negative infinity
That is [tex]\lim_{x \to 7^{-}} \frac{1}{x-7} =- \infty[/tex].
Ans: A.
ANSWER TO Q9
The graph of the given piece-wise function is show as follows;
We can see from the graph that, as the x-values are approaching 3 from the left y-values are approaching [tex]1.5[/tex].
Note the limit is not the same as the functional value in this case. Also limit in this case is the y-value we are approaching as we get closer and closer to 3, not necessarily at 3.
See graph
Ans: B
ANSWER TO Q10
The given function is [tex]f(x)=\frac{x^3+1}{x^5}[/tex]
We want to find the limiting value of this function as the x-values approaches zero.
Thus,
[tex]\lim_{x \to 0} f(x)=\frac{x^3+1}{x^5}[/tex]
Since the function is not defined at [tex]x=0[/tex].
We evaluate the one-sided limits as follows,
[tex]\lim_{x \to 0^-} f(x)=\frac{x^3+1}{x^5}=- \infty[/tex]
[tex]\lim_{x \to 0^+} f(x)=\frac{x^3+1}{x^5}=+ \infty[/tex]
Since the right hand limit is not equal to the left hand limit,
[tex]\lim_{x \to 0} f(x)=\frac{x^3+1}{x^5}[/tex] Does Not Exist.
ANS: C
ANSWER TO Q11
The given function is
[tex]f(x)=-\frac{3}{x}[/tex]
To find the derivative of this function at,
[tex]x=-4[/tex], we must first differentiate this function.
But let us rewrite the rational function as a power function so that it will be easier to differentiate using the power rule of differentiation.
That is,
[tex]f(x)=-3x^{-1}[/tex].
We differentiate now to obtain,
[tex]f'(x)=-1(-3x^{-1-1})[/tex]
This implies that,
[tex]f'(x)=3x^{-2}[/tex]
[tex]f'(x)=\frac{3}{x^2}[/tex]
At [tex]x=-4[/tex]
[tex]f'(1)=\frac{3}{(-4)^2}[/tex]
[tex]f'(1)=\frac{3}{(16)}[/tex]
Ans: B
ANSWER TO Q12
We want to find the limit of the function [tex]f(x)=x^2-2[/tex] as x approaches zero.
[tex]\lim_{x \to 0} x^2-2[/tex]
This is a polynomial function, therefore
[tex]\lim_{x \to 0} x^2-2=f(0)=0^2-2=-2[/tex]
Ans: B
SEE ATTACHMENT FOR ANSWER TO QUESTIONS
13, 14 and 15
