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Algebraic Manipulation in Limit Evaluation
Evaluate the limit $$\lim_{x \to 1} \frac{x^3 - 1}{x - 1}$$.
Analysis of One-Sided Limits and Jump Discontinuity
Consider the piecewise function $$ f(x)=\begin{cases}3x+1,& x<2,\\ x^2,& x \ge 2.\end{cases} $$ Ans
Analyzing Limits from Experimental Data (Table)
The table below shows measured values of a function $$f(x)$$ near $$x = 1$$. | x | f(x) | |-----
Analyzing Process Data for Continuity
A manufacturing process produces items whose lengths (in mm) are recorded as a function f(x) of time
Asymptotic Analysis of a Rational Function
Consider the function $$f(x)= \frac{4*x^2 - 1}{2*x^2+3*x}$$.
Combined Limit Analysis of a Piecewise Function
Consider the function $$f(x)= \begin{cases} \frac{x^2-1}{x-1} & \text{if } x \neq 1, \\ c & \text{if
Composite Function and Continuity Analysis
Define \(f(x)=\sqrt{1-\ln(x)}\) for \(x>0\) and consider the composite function \(g(x)=f(e^x)\). Ans
Continuity Analysis with a Piecewise-defined Function
A particle’s displacement is described by the piecewise function $$s(t)= \begin{cases} t^2+1, & t <
Continuity and Asymptotic Behavior of a Rational Exponential Function
Consider the function $$q(x)= \frac{e^{2*x} - 4}{e^{x} - 2}$$. Notice that the function is not defin
Continuity and Composition of Functions
Consider two functions: $$ f(x)=\frac{x^2-1}{x-1} $$ for $$x\ne1$$, and the piecewise function $$ g(
Continuity in a Piecewise Function with Square Root and Rational Expression
Consider the function $$f(x)=\begin{cases} \sqrt{x+6}-2 & x<-2 \\ \frac{(x+2)^2}{x+2} & x>-2 \\ 0 &
Direct Evaluation of Polynomial Limits
Let $$ f(x)=x^3-5*x+2 $$.
Estimating Derivatives Using Limit Definitions from Data
The position of an object (in meters) is recorded at various times (in seconds) in the table below.
Evaluating Sequential Limits in Particle Motion
A particle’s velocity is given by the function $$v(t)= \frac{(t-2)(t+4)}{t-2}$$ for $$t \neq 2$$, an
Factorization and Limit Evaluation
Consider the function $$f(x) = \frac{x^3 - 8}{x - 2}$$. (a) Factor the numerator and simplify the e
Factorization and Removable Discontinuity
Consider the function $$f(x) = \frac{x^2 - 9}{x - 3}$$ for $$x \neq 3$$. Answer the following:
Graph Analysis: Identify Limits and Discontinuities
A graph of a function f(x) is provided in the stimulus. The graph shows a removable discontinuity at
Graph Transformations and Continuity
Let $$f(x)=\sqrt{x}$$ and consider the function $$g(x)= f(x-2)+3= \sqrt{x-2}+3$$.
Intermediate Value Theorem in Equation Solving
A continuous function defined on [0, 10] is given by $$f(x)= \frac{x}{10} - \sin(x)$$.
Investigating Discontinuities in a Rational Function
Consider the function $$ h(x)=\frac{x^2-4}{x-2} $$ for $$x\ne2$$.
Jump Discontinuity in a Piecewise Function
Consider the function $$f(x)=\begin{cases} x+2, & x < 1 \\ 3, & x = 1 \\ 2*x, & x > 1 \end{cases}$$.
Limit Analysis in Population Modeling
A population is modeled by the function $$P(t)= \frac{1000*t}{t+5}$$ where $$t \geq 0$$ (in years).
Limit Involving a Square Root and Removable Discontinuity
Consider the function $$h(x)=\frac{\sqrt{x+4}-2}{x}$$ for $$x\neq0$$ and $$h(0)=1$$. Answer the foll
Limit Involving Radical Expressions
For the function $$f(x)=\frac{\sqrt{x+9}-3}{x}$$, evaluate the limit as x approaches 0.
Limits Involving Absolute Value Expressions
Evaluate the limit $$\lim_{x \to 0} \frac{|x|}{x}$$.
Limits Involving Absolute Value Functions
Consider the function $$ f(x)=\frac{|x-3|}{x-3} $$.
Limits Involving Composition and Square Roots
Consider the function $$ f(x)=\sqrt{x+4}-2 $$.
Limits Involving Radical Functions
Evaluate the limit $$\lim_{x \to 4} \frac{\sqrt{x} - 2}{x - 4}$$.
Long-Term Behavior of Particle Motion: Horizontal Asymptotes
For a particle, the velocity function is given by $$v(t)= \frac{4*t^2-t+1}{t^2+2*t+3}$$. Answer the
One-Sided Limits and Absolute Value Functions
Let $$f(x) = \frac{|x - 2|}{x - 2}$$. Analyze its behavior as x approaches 2.
One-Sided Limits and Vertical Asymptotes
Consider the function $$ f(x)= \frac{1}{x-4} $$.
Piecewise Function Continuity and IVT
Let $$f(x)=\begin{cases} x^2, & x \leq 1 \\ a*x+b, & x > 1 \end{cases}$$. Determine constants a and
Rational Function with Two Critical Points
Consider the function $$f(x)=\begin{cases} \frac{x^2+x-6}{x^2-9} & x\neq -3,3 \\ \frac{5}{6} & x=-3
Removable Discontinuity and Limit
Consider the function $$ f(x)=\frac{x^2-9}{x-3} $$ for $$ x\ne3 $$, which is not defined at $$ x=3 $
Removable Discontinuity and Limit Evaluation
Consider the function $$f(x) = \frac{(x + 3) * (x - 2)}{x + 3}$$ for $$x \neq -3$$. Answer the follo
Removable Discontinuity and Redefinition
Consider the function $$f(x)=\frac{x^2-4}{x-2}$$ for $$x\neq2$$. Note that f is undefined at $$x=2$$
Removable Discontinuity in a Cubic Function
Consider the function $$f(x)=\begin{cases} \frac{x^3-27}{x-3} & x\neq3 \\ 10 & x=3 \end{cases}$$. An
Removing Discontinuities
Consider the function $$f(x)=\frac{x^2-9}{x-3}$$.
Squeeze Theorem Application
Let $$f(x)=x^2\sin(1/x)$$ for \(x\neq 0\) and define \(f(0)=0\). Use the Squeeze Theorem to complete
Water Tank Inflow-Outflow Analysis
Consider a water tank operating over the time interval $$0 \le t \le 12$$ minutes. The water inflow
Acceleration Through Successive Differentiation
A particle’s position is given by $$s(t)=t^3-6*t^2+9*t+4$$ (with s in meters and t in seconds). Answ
Analysis of Motion in the Plane
A particle moves in the plane with its position given by $$\mathbf{s}(t)=\langle t^2 - 4*t,\, 3*t +
Analyzing a Function's Derivative from its Graph
A graph of a smooth function is provided. Answer the following questions:
Analyzing Concavity and Inflection Points Using Derivatives
Let $$f(x)=x^4 - 4*x^3 + 6*x^2$$. Answer the following questions:
Application of the Quotient Rule: Velocity on a Curve
A car's velocity is modeled by $$v(t)= \frac{2*t+3}{t+1}$$, where $$t$$ is measured in seconds. Anal
Approximating the Instantaneous Rate of Change Using Secant Lines
A function $$f(t)$$ models the position of an object. The following table shows selected values of $
Approximating the Tangent Slope
Consider the function $$f(x)=3*x^2$$. Answer the following:
Car Fuel Consumption vs. Refuel
A car is being refueled at a constant rate of $$4$$ liters/min while it is being driven. Simultaneou
Derivative from First Principles
Derive the derivative of the polynomial function $$f(x)=x^3+2*x$$ using the limit definition of the
Derivative of an Exponential Decay Function
Consider the function $$f(t)=e^{-0.5*t}$$, which may represent the decay of a substance over time. A
Derivative using the Limit Definition for a Linear Function
For the linear function $$f(x)= 5*x - 3$$, perform an analysis of its derivative using the limit def
Derivatives in Economics: Cost Functions
A company's production cost is modeled by $$C(q)=500+20*q-0.5*q^2$$, where $$q$$ represents the quan
Derivatives of Trigonometric Functions
Let $$f(x)=\sin(x)+\cos(x)$$, where $$x$$ is measured in radians. This function may represent a comb
Derivatives on an Ellipse
The ellipse given by $$\frac{x^2}{9} + \frac{y^2}{4} = 1$$ represents a race track. Answer the follo
Differentiation of a Composite Motion Function
A particle’s position is given by $$s(t) = t^2 * \ln(t)$$ for $$t > 0$$. Use differentiation to anal
Differentiation of a Log-Linear Function
Consider the function $$f(x)= 3 + 2*\ln(x)$$ which might model a process with a logarithmic trend.
Evaluating Derivative of a Composite Function using the Definition
Consider the function $$h(x)=\sqrt{4+x}$$. Answer the following questions:
Finding Derivatives of Composite Functions
Let $$f(x)= (3*x+1)^4$$.
Finding the Tangent Line Using the Product Rule
For the function $$f(x)=(3*x^2-2)*(x+5)$$, which models a physical quantity's behavior over time (in
Graph vs. Derivative Graph
A graph of a function $$f(x)$$ and a separate graph of its derivative $$f'(x)$$ are provided in the
Implicit Differentiation of a Circle
Consider the equation $$x^2 + y^2 = 25$$ representing a circle with radius 5. Answer the following q
Inverse Function Analysis: Cubic Transformation
Consider the function $$f(x)=(x-1)^3$$ defined for all real numbers.
Inverse Function Analysis: Hyperbolic-Type Function
Consider the function $$f(x)=\sqrt{x^2+1}$$ defined for $$x\geq0$$.
Inverse Function Analysis: Quadratic Function
Consider the function $$f(x)=x^2$$ restricted to $$x\geq0$$.
Limit Definition for a Quadratic Function
For the function $$h(x)=4*x^2 + 2*x - 7$$, answer the following parts using the limit definition of
Marginal Cost from Exponential Cost Function
A company’s cost function is given by $$C(x)= 500*e^{0.05*x} + 200$$, where $$x$$ represents the num
Marginal Profit Calculation
A company’s profit (in thousands of dollars) is given by $$P(x)= -2*x^2 + 50*x - 100$$, where $$x$$
Mountain Stream Flow Adjustment
A mountain stream receives additional water from snowmelt at a rate of $$f(t)=4*t$$ (cubic feet/seco
Polynomial Rate of Change Analysis
Consider the function $$f(x)= x^3 - 2*x^2 + x$$, which models a physical process. Analyze the rates
Product Rule Application in Economics
A company's cost function for producing $$x$$ units is given by $$C(x)= (3*x+2)*(x^2+5)$$ (cost in d
Rate of Chemical Reaction
The concentration of a reactant in a chemical reaction is modeled by \(C(t)=10*e^{-0.3*t}\), where \
RC Circuit Voltage Decay
An RC circuit's capacitor voltage is modeled by $$V(t)= V_{0}*e^{-t/(R*C)}$$, where $$V_{0}$$ is the
Related Rates: Balloon Surface Area Change
A spherical balloon has volume $$V=\frac{4}{3}\pi r^3$$ and surface area $$S=4\pi r^2$$. If the volu
Riemann Sums and Derivative Estimation
A car’s position $$s(t)$$ in meters is recorded in the table below at various times $$t$$ in seconds
Sand Pile Growth with Erosion Dynamics
A sand pile is growing as sand is added at a rate of $$f(t)=8+0.3*t$$ (kg/min) and simultaneously lo
Secant and Tangent Lines Analysis
Consider the function $$g(t)=t^3-6*t^2+9*t+2$$ modeling the height (in meters) of a ball at time $$t
Secant and Tangent Lines for a Cubic Function
Consider the function $$f(x)= x^3 - 4*x$$.
Secant and Tangent Lines to a Curve
Consider the function $$f(x)=x^2 - 4*x + 5$$. Answer the following questions:
Secant Approximation Convergence and the Derivative
Consider the natural logarithm function $$f(x)= \ln(x)$$. Investigate its rate of change using the d
Secant Slope from Tabulated Data
A table below gives values of a function $$f(x)$$ representing the concentration of a solution at di
Tangent Line Approximation for a Cubic Function
Let $$f(x)=2*x^3 - 7*x + 1$$. At $$x=1$$, determine the equation of the tangent line and use it to a
Tangent to an Implicit Curve
Consider the curve defined implicitly by \(x^2 + y^2 = 25\). Answer the following parts.
Using the Limit Definition of the Derivative
Consider the function $$g(x)=3*x^3-2*x+5$$, which models the cost (in dollars) of manufacturing $$x$
Analyzing a Function and Its Inverse
Consider the invertible function $$f(x)= \frac{x^3+1}{2}$$.
Chain Rule with Trigonometric and Exponential Functions
Let $$y = \sin(e^{3*x})$$. Answer the following:
Chemical Reaction Rate: Exponential and Logarithmic Model
The concentration of a chemical reaction is modeled by $$C(t)= \ln\left(3*e^(2*t) + 7\right)$$, wher
Combining Chain Rule, Implicit, and Inverse Differentiation
Consider the equation $$\sqrt{x+y}+\ln(y)=x^2$$, where $$y$$ is defined implicitly as a function of
Composite Differentiation of an Inverse Trigonometric Function
Let $$H(x)= \arctan(\sqrt{x+3})$$.
Composite Function Differentiation in a Sand Pile Model
Sand is added to a pile at an inflow rate of $$A(t)= 4 + t^2$$ (kg/min) and removed at an outflow ra
Composite Function with Inverse Trigonometric Outer Function
Consider the function $$H(x)=\arctan(\sqrt{x^2+1})$$. Answer the following parts.
Composite Log-Exponential Function Analysis
A function is defined by $$f(x)=\ln\left(e^(2*x^2) + 5\right)$$. This function is composed of an exp
Differentiation of Inverse Function with Polynomial Functions
Let \(f(x)= x^3+2*x+1\) be a one-to-one function. Its inverse is denoted by \(f^{-1}\).
Differentiation of Inverse Trigonometric Function via Implicit Differentiation
Let $$y=\arcsin(\frac{x}{\sqrt{2}})$$. Answer the following:
Differentiation of Inverse Trigonometric Functions in Physics
In an optics experiment, the angle of refraction \(\theta\) is given by $$\theta= \arcsin\left(\frac
Estimating Derivatives Using a Table
An experiment measures a one-to-one function $$f$$ and its inverse $$g$$, yielding the following dat
Expanding Spherical Balloon
A spherical balloon has its volume given by $$V=\frac{4}{3}\pi r^3$$. The radius of the balloon incr
Implicit Differentiation in Circular Motion
Consider the circle defined by the equation $$x^2+y^2=100$$, which could represent the track of an o
Implicit Differentiation Involving Logarithms
Consider the equation $$\ln(x) + x*y = \ln(y) + x$$ which relates $$x$$ and $$y$$. Use implicit diff
Implicit Differentiation of an Ellipse in Navigation
A flight path is modeled by the ellipse $$\frac{x^2}{16}+\frac{y^2}{9}=1$$.
Implicit Differentiation on a Circle
Consider the circle defined by $$x^2+y^2=25$$. Use implicit differentiation to find the slope of the
Implicit Differentiation with Mixed Functions
Consider the relation $$x\cos(y)+y^3=4*x+2*y$$.
Implicit Differentiation with Product Rule
Consider the implicit equation $$x*y+y^2=6$$ which defines $$y$$ as a function of $$x$$. Use implici
Implicit Differentiation: Combined Product and Chain Rules
Consider the equation $$x^2*y + \sin(x*y) = 0$$. Answer the following parts.
Inverse Function Derivative for a Log-Linear Function
Let $$f(x)= x+ \ln(x)$$ for $$x > 0$$ and let g be the inverse of f. Solve the following parts:
Inverse Function Derivative in Thermodynamics
A thermodynamic process is modeled by the function $$P(V)= 3*V^2 + 2*V + 5$$, where $$V$$ is the vol
Inverse Function Differentiation for a Log Function
Let $$f(x)=\ln(3*x+2)$$, and assume that $$f$$ is invertible with inverse function $$g$$. Find the d
Inverse Function Differentiation in Logarithmic Functions
Let $$f(x)=\ln(x+2)$$, which is one-to-one and has an inverse function $$g(y)$$. Answer the followin
Inverse Function in Currency Conversion
A function converting dollars to euros is given by $$f(d) = 0.9*d + 10\ln(d+1)$$ for $$d > 0$$. Let
Inverse Trigonometric Differentiation
Let $$L(x)=\arcsin\left(\frac{2*x}{1+x^2}\right)$$.
Optimization in a Container Design Problem
A manufacturer is designing a closed cylindrical container with a fixed volume of $$1000\,cm^3$$. Th
Particle Motion: Logarithmic Position Function
The position of a particle moving along a line is given by $$s(t)= \ln(3*t+2)$$, where s is in meter
Pendulum Angular Displacement Analysis
A pendulum's angular displacement is modeled by the function $$\theta(t)=\sin(2t^2+3)$$, where t is
Analyzing a Nonlinear Rate of Revenue Change
A company's revenue in thousands of dollars is modeled by the function $$R(x)=100\ln(x+1) + 0.5x$$,
Analyzing Position Data with Table Values
A moving object’s position, given by $$x(t)$$ in meters, is recorded in the table below. Use the dat
Critical Points and Concavity Analysis
Consider the polynomial function $$f(x)= x^4 - 4*x^3 + 6*x^2 - 4*x + 1$$ modeling the position of an
Defect Rate Analysis in Manufacturing
The defect rate in a manufacturing process is modeled by $$D(t)=100e^{-0.05t}+5$$ defects per day, w
Determining the Tangent Line
Consider the function $$f(x)=\ln(x)+ x$$. The graph of the function is provided for reference.
Differentiability of a Piecewise Function
Consider the piecewise function $$ f(x)=\begin{cases} x^2, & x \leq 2 \\ 4x-4, & x>2 \end{cases} $$
Drainage Analysis in a Conical Tank
Water is draining from a conical tank at a constant rate of 3 cubic meters per minute. The tank has
Error Approximation in Engineering using Differentials
The cross-sectional area of a circular pipe is given by $$A=\pi r^2$$. If the radius is measured as
Falling Object's Velocity Analysis
A rock is thrown upward from the top of a building with a velocity function $$v(t)= 20 - 9.8*t$$ (in
FRQ 10: Chemical Kinetics Analysis
In a chemical reaction, the concentration of reactant A, denoted by [A], and time t (in minutes) are
Graphing a Function via its Derivative
Consider the function $$f(x) = x^{1/3}$$ defined for all real numbers.
Inflating Spherical Balloon
A spherical balloon is being inflated such that its volume increases at a constant rate of $$\frac{d
Inverse Function Analysis in a Real-World Model
Consider the function $$f(x)=x^3+1$$ which models a certain transformation of measurable quantities.
L'Hôpital's Rule in Action
Evaluate the following limit by applying L'Hôpital's Rule as necessary: $$\lim_{x \to \infty} \frac{
Linear Approximation of ln(1.05)
Let $$f(x)=\ln(x)$$. Use linearization at x = 1 to approximate the value of $$\ln(1.05)$$.
Linearization and Differentials Approximation
A function $$f(x)= x^3$$ models the volume (in cubic centimeters) of liquid in a container as a func
Marginal Profit Analysis
A company's profit in thousands of dollars is given by $$P(x)= -0.5*x^2+20*x-50$$, where $$x$$ (in h
Maximizing Enclosed Area
A rancher has 120 meters of fencing to enclose a rectangular pasture along a straight river (the sid
Minimizing Materials for a Cylindrical Can
A manufacturer aims to design a closed cylindrical can that holds exactly $$500$$ cubic centimeters
Particle Motion with Changing Acceleration
A particle moves along a straight line with an acceleration given by $$a(t) = 6 - 4*t$$ (in m/s²), w
Population Growth Model and Asymptotic Limits
A population is modeled by $$P(t) = \frac{5000e^{0.1t}}{1 + e^{0.1t}}$$, where $$P(t)$$ is the popul
Projectile Motion: Maximum Height
A ball is thrown upward and its height is modeled by $$h(t)=-5t^2+20t+2$$ (in meters). Analyze its m
Related Rates: Expanding Circular Ripple
A ripple in a still pond expands in the shape of a circle. The area of the ripple is given by $$A=\p
Related Rates: Inflating Spherical Balloon
A spherical balloon is being inflated such that its volume increases at a constant rate of $$20$$ cu
Seasonal Water Reservoir
A reservoir's water volume (in million m³) changes with the seasons according to $$V(t)=5+2\sin\left
Shadow Length: Related Rates
A 15-foot tall lamp post casts light on a 6-foot tall man walking away from the lamp at 4 ft/sec. Le
Volume Change Analysis in a Swimming Pool
The volume of a pool is given by $$V(t)=8t^2-32t+4$$, where V is in gallons and t in hours. Analyze
Absolute Extrema via the Candidate's Test
Consider the function $$f(x)= \sqrt{x} - x$$ on the closed interval $$[0,4]$$. Use the candidate's t
Asymptotic Behavior in an Exponential Decay Model
Consider the model $$f(t)= 100*e^{-0.3*t}$$ representing a decaying substance over time. Answer the
Bacterial Culture Growth: Identifying Critical Points from Data
A microbiologist records the population of a bacterial culture (in millions) at different times (in
Biological Growth and the Mean Value Theorem
In a bacterial culture, the population is modeled by $$P(t)= 4*t^2 + 3*t + 7$$ for $$t$$ in hours on
Capacitor Discharge in an RC Circuit
The voltage across a capacitor during discharge is given by $$V(t)= V_0*e^{-t/(RC)}$$, where $$t$$ i
Concavity Analysis of a Cubic Function
Consider the function $$f(x)= x^3 - 6*x^2 + 9*x + 2$$. Use the second derivative to investigate the
Continuity Analysis of a Rational Piecewise Function
Consider the function $$f(x)$$ defined as $$ f(x) = \begin{cases} \frac{x^{2} - 4}{x-2}, & x \neq 2
Cubic Polynomial Analysis
Consider the cubic function $$f(x)= x^3 - 6*x^2 + 9*x + 2$$ defined on the interval $$[0,4]$$. Analy
Economic Demand and Revenue Optimization
The demand for a product is modeled by $$D(p) = 100 - 2*p$$, where $$p$$ is the price in dollars. Th
Finding Local Extrema Using the First Derivative Test
Consider the function $$f(x) = x^3 - 6*x^2 + 9*x + 2$$. Answer the following:
FRQ 6: Particle Motion with Variable Acceleration
A particle moves along a straight line with acceleration given by $$a(t) = 6 - 4*t$$ (in m/s²). At t
FRQ 9: Extreme Value Analysis for a Rational Function
Consider the function $$f(x) = \frac{x}{1+x^2}$$ defined on the interval [ -2, 2 ].
FRQ 10: First Derivative Test for a Cubic Profit Function
A company’s profit function is given by $$P(x)= x^3 - 9*x^2 + 24*x + 1$$, where $$x$$ represents the
FRQ 17: Analysis of a Trigonometric Function for Extrema and Inflection Points
Let $$f(x)= \sin(x) - 0.5*x$$ for $$x \in [0, 2\pi]$$.
FRQ 20: Profit Analysis Combining MVT and Optimization
A company’s profit function is given by $$P(x)= -2*x^3 + 18*x^2 - 48*x + 40$$, where $$x$$ (in thous
Increase and Decrease Analysis of a Polynomial Function
Consider the function $$f(x)= x^4 - 4*x^3 + 6*x^2 - 4*x + 1$$ on the interval $$[-1, 3]$$.
Inverse Analysis of a Composite Function
Consider the function $$f(x)=e^(x)+x$$. Although its inverse cannot be written in closed form, answe
Investigating the Behavior of a Composite Function
Consider the function $$f(x)= (x^2+1)*(x-3)$$. Answer the following:
Oil Spill Cleanup
In an oil spill scenario, oil continues to enter an affected area while cleanup efforts remove oil.
Optimization of a Rectangle Inscribed in a Semicircle
A rectangle is inscribed in a semicircle of radius 5 (with the base along the diameter). The top cor
Optimization of an Open-Top Box
A company is designing an open-top box with a square base. The volume of the box is modeled by the f
Pharmacokinetics: Drug Concentration Decay
A drug in the bloodstream decays according to $$D(t)= D_0*e^{-k*t}$$, where $$t$$ is in hours. Answe
Population Growth Analysis via the Mean Value Theorem
A country's population data over a period of years is given in the table below. Use the data to anal
Profit Function Concavity Analysis
A company’s profit is modeled by $$P(x) = -2*x^3 + 18*x^2 - 48*x + 10$$, where $$x$$ is measured in
Radioactive Substance Decay
A radioactive substance decays according to the model $$A(t)= A_0 * e^{-\lambda*t}$$, where $$t$$ is
Relative Extrema of a Rational Function
Examine the function $$f(x)= \frac{x+1}{x^2+1}$$ and determine its relative extrema using derivative
Revenue Optimization in Economics
A company's revenue is modeled by the function $$R(x)= x*e^{-0.1*x}$$, where $$x$$ (in thousands) re
Sign Analysis of f'(x)
The first derivative $$f'(x)$$ of a function is known to have the following behavior on $$[-2,2]$$:
Tangent Line to an Implicitly Defined Curve
The curve is defined by the equation $$x^2 + x*y + y^2 = 7$$.
Temperature Regulation in a Greenhouse
A greenhouse is regulated by an inflow of warm air and an outflow of cooler air. The inflow temperat
Transcendental Function Analysis
Consider the function $$f(x)= \frac{e^x}{x+1}$$ defined for $$x > -1$$ and specifically on the inter
Verifying the Mean Value Theorem for a Polynomial Function
Consider the function $$f(x) = x^3 - 3*x^2 + 4$$ defined on the interval $$[0, 3]$$. Answer the foll
Analyzing Bacterial Growth via Riemann Sums
A biologist measures the instantaneous growth rate of a bacterial population (in thousands of cells
Application of the Fundamental Theorem in a Discounted Cash Flow Model
A continuous cash flow is given by $$C(t)=500(1+0.05*t)$$ dollars per year. Using a continuous disco
Approximating the Area with Riemann Sums
Consider the linear function $$f(x) = 2*x + 1$$ on the interval $$[1,5]$$. Use Riemann sums to appro
Comparing Riemann Sum Methods for $$\int_1^e \ln(x)\,dx$$
Consider the function $$f(x)= \ln(x)$$ on the interval $$[1,e]$$. A table of approximate values is p
Comparing Riemann Sum Methods for a Complex Function
Consider the function $$f(x)=\frac{1}{1+x^2}$$ on the interval [0,1]. Answer the following:
Elevation Profile Analysis on a Hike
A hiker records the elevation (in meters) along a trail at various distances. Use this data to analy
Environmental Modeling: Pollution Accumulation
The pollutant enters a lake at a rate given by $$P(t)=5*e^{-0.3*t}$$ (in kg per day) for $$t$$ in da
Evaluating the Accumulated Drug Concentration
In a pharmacokinetics study, a drug is infused into a patient's bloodstream at a rate given by $$R(t
FRQ4: Inverse Analysis of a Trigonometric Accumulation Function
Let $$ H(x)=\int_{0}^{x} (\sin(t)+2)\,dt $$ for $$ x \in [0,\pi] $$, representing a displacement fun
Fuel Consumption Analysis
A truck's fuel consumption rate (in L/hr) is recorded at various times during a 12-hour drive. Use t
Integration by Parts: Evaluating $$\int_1^e \ln(x)\,dx$$
Evaluate the integral $$\int_1^e \ln(x)\,dx$$ using integration by parts.
Motion Under Variable Acceleration
A particle moves along the x-axis with acceleration $$a(t) = 6 - 4*t$$ (in m/s²) for $$0 \le t \le 3
Optimizing Fencing Cost for a Garden Adjacent to a River
A farmer plans to fence a rectangular garden adjacent to a river, so that no fence is required along
Particle Motion with Variable Acceleration
A particle moves along a straight line with an acceleration given by $$a(t) = 6 - 4*t$$ (in m/s²). T
Piecewise-Defined Function and Discontinuities
Consider the piecewise function $$f(x) = \begin{cases} \frac{x^2 - 4}{x-2} & \text{if } x \neq 2, \\
Rainfall Accumulation via Integration
A region experiences rain where the rate of rainfall (in inches per hour) is given by $$r(t)=0.5+0.2
Tabular Riemann Sums for Electricity Consumption
A household's daily electricity consumption (in kWh) over 5 consecutive days is recorded in the tabl
Temperature Change in a Chemical Reaction
During an exothermic chemical reaction, the temperature (in °C) is recorded over a 15-minute period.
Volume Accumulation in a Leaking Tank
Water leaks from a tank at a rate given by $$R(t)=3-0.5*t$$ (in liters per minute) for t in [0,6]. I
Work Done by a Variable Force
A force acting on an object is given by $$F(x)=3*x^2+2*x$$ where x is in meters and F in Newtons. Th
Bernoulli Differential Equation
Solve the Bernoulli differential equation $$\frac{dy}{dx}-\frac{1}{x}y=-x*y^2$$ for $$x>0$$ with the
Chemical Reaction Rate and Concentration Change
The rate of a chemical reaction is described by the differential equation $$\frac{dC}{dt}=-0.3*C^2$$
Direction Fields for an Autonomous Equation
Consider the differential equation $$\frac{dy}{dx}=y^2-9$$. Analyze the behavior of its solutions.
Environmental Pollution Model
Pollutant concentration in a lake is modeled by the differential equation $$\frac{dC}{dt}=\frac{R}{V
Epidemic Spread with Limited Capacity
In a closed community, the number of infected individuals $$I(t)$$ (in people) is modeled by the log
Implicit Differentiation of a Circle
Consider the circle defined by $$x^2+ y^2= 25$$. Answer the following:
Implicit Differentiation of a Transcendental Equation
Consider the equation $$e^{x*y} + y^3= x$$. Answer the following:
Linear Differential Equation using Integrating Factor
Solve the linear differential equation $$\frac{dy}{dx} + 2y = x$$ with the initial condition $$y(0)=
Logistic Growth in a Population
A population $$P(t)$$ grows according to the logistic differential equation $$\frac{dP}{dt}=0.5P\lef
Logistic Population Growth
A population grows according to the logistic model $$\frac{dP}{dt}= r * P\left(1-\frac{P}{K}\right)$
Mixing Problem with Variable Inflow Concentration
A tank initially contains 50 L of water with 5 kg of dissolved salt. A solution enters the tank at a
Mixing Tank Problem
A tank initially contains $$100$$ liters of pure water. A salt solution with a concentration of $$0.
Mixing with Variable Inflow Rate
A 50-liter tank initially contains water with 1 kg of dissolved salt. Water containing 0.2 kg of sal
Modeling Continuous Compound Interest
An account accrues interest continuously according to the differential equation $$\frac{dA}{dt}=rA$$
Modeling Cooling with Newton's Law of Cooling
A hot beverage cools according to Newton's Law of Cooling, modeled by the differential equation $$\f
Motion Under Gravity with Air Resistance
An object is falling vertically under the influence of gravity and air resistance. Its velocity $$v(
Newton's Law of Cooling
A hot object is placed in a room with constant temperature $$20^\circ C$$. Its temperature $$T$$ sat
Oil Spill Cleanup Dynamics
To mitigate an oil spill, a cleanup system is employed that reduces the volume of oil in contaminate
Radioactive Decay
A radioactive substance decays according to $$\frac{dy}{dt} = -0.05\,y$$ with an initial mass of $$y
Radioactive Decay with Production
A radioactive substance decays while being produced at a constant rate, and its mass $$M(t)$$ (in kg
Related Rates: Conical Tank Filling
Water is pumped into a conical tank at a rate of $$3$$ m$^3$/min. The tank has a height of $$4$$ m a
Related Rates: Expanding Balloon
A spherical balloon is inflated such that its radius increases at a constant rate of $$\frac{dr}{dt}
Salt Tank Mixing Problem
A tank initially contains 100 liters of pure water. A salt solution with concentration 0.5 kg/L is p
Separable Differential Equation: $$dy/dx = x*y$$
Consider the differential equation $$dy/dx = x*y$$ with the initial condition $$y(0)=2$$. Solve the
Separable Differential Equation: Growth Model
Consider the separable differential equation $$\frac{dy}{dx} = 3*x*y$$ with the initial condition $$
Slope Field and General Solution
Consider the differential equation $$\frac{dy}{dx}=x$$. The attached slope field shows the slopes at
Solving a Differential Equation Using the SIPPY Method
Solve the differential equation $$\frac{dy}{dx}=4*x^3*e^{-y}$$ with the initial condition $$y(1)=0$$
Soot Particle Deposition
In an environmental study, the thickness $$P$$ (in micrometers) of soot deposited on a surface is me
Tank Mixing with Salt
In a mixing problem, a tank contains salt that is modeled by the differential equation $$\frac{dS}{d
Temperature Regulation in a Greenhouse
The temperature $$T$$ (in °F) inside a greenhouse is recorded over time (in hours) as shown. The war
Accumulated Electrical Charge from a Current Function
An electrical device charges according to the current function $$I(t)= 10*e^{-0.3*t}$$ amperes, wher
Accumulated Nutrient Intake from a Drip
A medical nutrient drip administers a nutrient at a variable rate given by $$N(t)=-0.03*t^2+1.5*t+20
Area Between \(\ln(x+1)\) and \(\sqrt{x}\)
Consider the functions $$f(x)=\ln(x+1)$$ and $$g(x)=\sqrt{x}$$ over the interval $$[0,3]$$.
Average Temperature Analysis
A researcher models the temperature during a day using the function $$T(t)=10+15*\sin\left(\frac{\pi
Average Temperature of a Cooling Liquid
The temperature of a cooling liquid is modeled by $$T(t)=50*e^{-0.1*t}+20$$ (in $$^\circ C$$) for $$
Average Temperature Over a Day
In a city, the temperature (in $$^\circ C$$) is modeled by $$T(t)=10+5*\cos\left(\frac{\pi*t}{12}\ri
Average Voltage in a Physics Experiment
In a physics experiment, the voltage across a resistor is modeled by $$V(t)=5+3*\cos\left(\frac{\pi*
Center of Mass of a Lamina with Variable Density
A thin lamina occupies the interval $$[0,4]$$ along the x-axis and has a variable density $$\delta(x
Determining Velocity and Position from Acceleration
A particle moves along a line with acceleration given by $$a(t)=4-2*t$$ (in $$m/s^2$$). At time $$t=
Distance Traveled by a Jogger
A jogger increases her daily running distance by a fixed amount. On the first day she runs $$2$$ km,
Exponential Decay Function Analysis
A lab experiment models the decay of a chemical concentration with the function $$f(t)=8*e^{-0.5*t}$
Ice Rink Design: Volume and Area
An ice rink is designed with a cross-sectional profile given by $$y=4-x^2$$ (with y=0 as the base).
Integrated Motion Analysis
A particle moving along a straight line has an acceleration given by $$a(t)= 4 - 6*t$$ (in m/s²) for
Net Change in Biological Population
A species' population changes at a rate given by $$P'(t)=0.5e^{-0.2*t}-0.05$$ (in thousands per year
Pipeline Installation Cost Analysis
The cost to install a pipeline along a route is given by $$C(x)=100+5*\sin(x)$$ (in dollars per mete
Population Growth Rate Analysis
Suppose the instantaneous growth rate of a population is given by $$r(t)=0.04 - 0.002*t$$ for $$t \i
Radioactive Decay Accumulation
A radioactive substance decays at a rate given by $$r(t)= C*e^{-k*t}$$ grams per day, where $$C$$ an
Rebounding Ball
A ball is dropped from a height of $$16$$ meters. Each time the ball bounces, its maximum height is
River Discharge Analysis
The flow rate of a river is modeled by $$Q(t)=20+5*\sin\left(\frac{\pi*t}{12}\right)$$ (in cubic met
Tank Filling Process Analysis
Water flows into a tank at a rate modeled by $$R(t)=5+0.5*t$$ (in liters per minute) for $$0 \le t \
Temperature Average Calculation
A scientist records the temperature in a lab using a continuous function $$T(t)=3*t^2 - 4*t + 5$$, w
Temperature Increase in a Chemical Reaction
During a chemical reaction, the rate of temperature increase per minute follows an arithmetic sequen
Volume by the Disc Method for a Rotated Region
Consider a function $$f(x)$$ that represents the radius (in cm) of a region rotated about the x-axis
Volume of a Rotated Region by the Disc Method
Consider the region bounded by the curve $$f(x)=\sqrt{x}$$ and the line $$y=0$$ for $$0 \le x \le 4$
Volume of a Solid of Revolution Using the Washer Method
The region bounded by the curves $$x=\sqrt{y}$$ and $$x=\frac{y}{2}$$ for $$y\in[0,4]$$ is revolved
Volume of a Solid with Square Cross Sections
A solid has a base in the xy-plane given by the region bounded by the curves $$y=x$$ and $$y=\sqrt{x
Volume with Semicircular Cross-Sections
A solid has a base on the interval $$[0,3]$$ along the x-axis, and its cross-sectional slices perpen
Volume with Square Cross-Sections
Consider the region bounded by the curve $$y=x^2$$ and the line $$y=4$$ for $$0 \le x \le 2$$. Squar
Washer Method with Logarithmic and Exponential Curves
Consider the region bounded by the curves $$f(x)=\ln(x+1)$$ and $$g(x)=e^{-x}$$ on the interval $$[0
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