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Analysis of a Jump Discontinuity
Consider the function $$f(x)=\begin{cases} 3*x+1, & x<4 \\ 2*x-3, & x\geq4 \end{cases}$$.
Analyzing Limits of a Combined Exponential‐Log Function
Consider $$f(x)= e^{-x}\,\ln(1+\sqrt{x})$$ for $$x \ge 0$$. Analyze the limits as $$x \to 0^+$$ and
Application of the Squeeze Theorem with Trigonometric Oscillations
Consider the function $$f(x)= x^2*\sin(1/x)$$ for $$x \neq 0$$ and $$f(0)=0$$. Answer the following
Approximating Limits Using Tabulated Values
The function g(x) is sampled near x = 2 and the following values are recorded: | x | g(x) | |--
Asymptotic Behavior and Horizontal Limits
Consider the function $$f(x)=\frac{2 * x^2 - x + 1}{x^2+1}$$. Answer the following questions regardi
Car Braking Distance and Continuity
A car decelerates to a stop, and its velocity $$v(t)$$ in m/s is recorded in the following table, wh
Computing a Limit Using Algebraic Manipulation
Evaluate the limit $$\lim_{x\to2} \frac{x^2-4}{x-2}$$ using algebraic manipulation.
Continuity Analysis in Road Ramp Modeling
A highway ramp is modeled by the function $$y(x)= \frac{(x-3)(x+2)}{x-3}$$ for $$x\neq3$$, where x i
Continuity Assessment of a Rational Function with a Redefined Value
Consider the function $$r(x)= \begin{cases}\frac{x^2-9}{x-3}, & x \neq 3 \\ 7, & x=3\end{cases}$$.
Continuity in Piecewise Functions with Parameters
A function is defined piecewise by $$f(x)=\begin{cases}a*x^2+3,& x<1,\\ b*x+1,& x\ge 1.\end{cases}$$
Determining Continuity via Series Expansion
Consider the function $$f(x)= \frac{e^x - \ln(1+x) - x - 1}{x^2}$$ for $$x \neq 0$$ with $$f(0)=L$$.
Epsilon-Delta Proof for a Polynomial Function
Let $$f(x)=x^2+3*x+2$$. Answer the following:
Graph Analysis of Discontinuities
A function $$q(x)$$ is defined piecewise as follows: $$q(x)=\begin{cases} x+2, & x<1, \\ 4, & x=1,
Graphical Analysis of Volume with a Jump Discontinuity
A graph of the water volume \(V(t)\) in a tank shows a jump discontinuity at \(t=6\) minutes. Answer
Implicitly Defined Function and Differentiation
Consider the curve defined implicitly by the equation $$x*y + \sin(x) + y^2 = 10$$. Answer the follo
Intermediate Value Theorem in Engineering Context
In a structural analysis, the stress on a beam is modeled by a continuous function $$S(x)$$ on the i
Inverse Function Analysis and Continuity
Consider the function $$f(x)=\frac{x-3}{2*x+5}$$. Answer the following:
Left-Hand and Right-Hand Limits for a Sign Function
Consider the function $$f(x)= \frac{x-2}{|x-2|}$$.
Limit and Continuity with Parameterized Functions
Let $$ f(x)= \frac{e^{3x} - 1 - 3x}{\ln(1+4x) - 4x}, $$ for $$x \neq 0$$ and define \(f(0)=L\) for c
Limit Evaluation Involving Radicals and Rationalization
Evaluate the limit $$\lim_{x \to 4} \frac{\sqrt{x}-2}{x-4}$$.
Limits and Continuity of Radical Functions
Examine the function $$f(x)= \frac{\sqrt{x+4}-2}{x}$$ defined for $$x \neq 0$$.
Modeling Temperature Change with Continuity
A city’s temperature throughout the day is modeled by the continuous function $$T(t)=\frac{1}{2}t^2-
Pendulum Oscillations and Trigonometric Limits
A pendulum’s angular displacement from the vertical is given by $$\theta(t)= \frac{\sin(2*t)}{t}$$ f
Rational Function Analysis of a Drainage Rate
A drain’s outflow rate is given by $$R_{out}(t)=\frac{3\,t^2-12\,t}{t-4}$$ for \(t\neq4\). Answer th
Rational Functions and Limit at Infinity
Consider the rational function $$r(x)= \frac{2x^2+3x-1}{x^2-4}$$.
Saturation of Drug Concentration in Blood
A patient is given a drug with each dose containing 50 mg. However, due to metabolism, only 20% of t
Squeeze Theorem with Oscillatory Behavior
Examine the function $$s(x)=x^2*\sin(1/x)$$ for x ≠ 0.
Trigonometric Limits
Consider the function $$f(x)=\frac{\sin(3*x)}{x}$$. Answer the following:
Chain Rule in Biological Growth Models
A biologist models the growth of a bacterial population by the function $$P(t) = (5*t + 2)^4$$, wher
Composite Function and Chain Rule Application
Consider the function $$h(x)=\sin(2*x^2+3)$$. Using the chain rule, answer the following parts:
Derivative from First Principles
Let $$f(x)=\sqrt{x}$$. Use the limit definition of the derivative to find $$f'(x)$$.
Derivative of a Composite Function Using the Limit Definition
Consider the function $$h(x)=(2*x+3)^3$$. Use the limit definition of the derivative to answer the f
Derivative via Quotient Rule: Fluid Flow Rate
A function describing the rate of fluid flow is given by $$f(x)= \frac{x^2+2}{3*x-1}$$.
Differentiating a Series Representing a Function
Consider the function defined by the infinite series $$S(x)= \sum_{n=0}^\infty \frac{(-1)^n * x^{2*
Differentiation from First Principles
Let $$h(x)=3*x^2+2*x-1$$. Use the limit definition of the derivative to analyze this function.
Epidemic Spread Rate: Differentiation Application
The number of infected individuals in an epidemic is modeled by $$I(t)= \frac{200}{1+e^{-0.5(t-5)}}$
Evaluating the Derivative Using the Limit Definition
Consider the function $$f(x) = 3*x^2 - 2*x + 1$$. (a) Use the limit definition of the derivative:
Finding and Interpreting Critical Points and Derivatives
Examine the function $$f(x)=x^3-9*x+6$$. Determine its derivative and analyze its critical points.
Higher-Order Derivatives
Consider the function $$f(x)=x^4 - 2*x^3 + 3*x -1$$. Answer the following:
Icy Lake Evaporation and Refreezing
An icy lake gains water from melting ice at a rate of $$M_{in}(t)=5+0.2*t$$ liters per hour and lose
Implicit Differentiation for a Rational Equation
Consider the curve defined by $$\frac{x*y}{x+y} = 3$$.
Instantaneous Rate of Change in Motion
A particle moves along a straight line with position given by $$s(t)=t^3-6*t^2+9*t+2$$, where $$t$$
Limit Definition of Derivative for a Rational Function
For the function $$f(x)=\frac{1}{x+1}$$, use the limit definition of the derivative to answer the fo
Maclaurin Series and Convergence for 1/(1-x)
An economist is using the function $$f(x)=\frac{1}{1-x}$$ to model economic behavior. Analyze the Ma
Maclaurin Series for e^x Approximation
Consider the function $$f(x)=e^x$$, which models many growth processes in nature. Use its Maclaurin
Optimization Using Derivatives
Consider the quadratic function $$f(x)=-x^2+4*x+5$$. Answer the following:
Particle Motion in the Plane
A particle moves in the plane with its position given by $$x(t)=t^2-4*t+1$$ and $$y(t)=3*t-2.5$$, wh
Pollutant Levels in a Lake
A lake receives pollutants at a rate of $$P_{in}(t)=30-0.5*t$$ concentration units per day and a tre
Population Growth Rates
A city’s population (in thousands) was recorded over several years. Use the data provided to analyze
Product and Quotient Rules in Economic Modeling
A company’s revenue (in thousands of dollars) is modeled by the function $$R(x)= (x+2)(x-1)$$ where
Rate of Change Analysis in a Temperature Model
A temperature model is given by $$T(t)=25+4*t-0.5*t^2$$, where $$t$$ is time in hours. Analyze the t
Related Rates: Changing Shadow Length
A 1.8 m tall man is walking away from a 5 m tall lamp at a constant speed of 1.2 m/s. The lamp casts
Reservoir Management Problem
A reservoir used for irrigation receives water at a rate of $$I(t)=20+2\sin(t)$$ liters per hour and
Satellite Orbit Altitude Modeling
A satellite’s altitude (in kilometers) above Earth is modeled by $$a(t)= 500*\cos\left(\frac{\pi}{6}
Secant and Tangent Approximations from a Graph
A function f(t) has been graphed from t = 0 to 10 seconds. Use the graph to estimate rates of change
Secant Line Approximation in an Experimental Context
A temperature sensor records the following data over a short experiment:
Tangent Line to a Logarithmic Function
Consider the function $$f(x)= \ln(x+1)$$.
Widget Production Rate
A widget manufacturing plant produces widgets according to the function $$P(t)=4*t^2 - 3*t + 10$$ wh
Chain Rule and Taylor/Maclaurin Series for an Exponential Function
Consider the function $$h(x) = e^{\sin(2*x)}$$, which is a composite of the exponential and sine fun
Chain Rule Application: Differentiating a Nested Trigonometric Function
Consider the function $$f(x) = \sin(\cos(2*x))$$. Analyze its derivative using the chain rule.
Chain Rule in a Nested Composite Function
Consider the function $$f(x)= \sin\left(\ln((2*x+1)^3)\right)$$. Answer the following parts:
Composite and Implicit Differentiation with Trigonometric Functions
Consider the equation $$\sin(x*y)+x^2=y^2$$ which relates x and y. Answer the following parts:
Differentiation of a Log-Exponential Composition with Critical Points
Consider the function $$k(x)=x*\ln(e^{x}+3)$$. Answer the following parts.
Differentiation of an Inverse Trigonometric Form
Consider the function $$f(x)=\arcsin\left(\frac{2*x}{1+x^2}\right)$$. Answer the following parts.
Differentiation of an Inverse Trigonometric Function
Define $$h(x)= \arctan(\sqrt{x})$$. Answer the following:
Implicit Differentiation and Concavity of a Logarithmic Curve
The curve defined implicitly by $$y^3 + x*y - \ln(x+y) = 5$$ is given. Use implicit differentiation
Implicit Differentiation in an Economic Model
A company’s production is modeled by the implicit relationship $$x*y^2 + \ln(x+y) = 10$$, where $$x$
Implicit Differentiation in Economic Equilibrium
In a market, the relationship between the price $$x$$ (in dollars) and the demand $$y$$ (in thousand
Implicit Differentiation of an Implicit Curve
Consider the curve defined by $$x*y + x^2 - y^2 = 5$$. Answer the following parts.
Implicit Differentiation: Conic Section Analysis
Consider the conic section defined by $$x^2 + 3*x*y + y^2 = 5$$. Answer the following:
Implicit Equation with Logarithmic and Exponential Terms
The relation $$\ln(x+y)+e^{x-y}=3$$ defines y implicitly as a function of x. Answer the following pa
Inverse Analysis of Cubic Plus Linear Function
Consider the function $$f(x)=x^3+x$$ defined for all real numbers. Analyze its inverse function.
Inverse Function Derivative in an Exponential Model
Let $$f(x)= e^{2*x} + x$$. Given that $$f$$ is one-to-one and differentiable, answer the following p
Inverse Function Differentiation Basics
Let $$f$$ be a one-to-one differentiable function with $$f(3)=5$$ and $$f'(3)=2$$, and let $$g$$ be
Inverse Function Differentiation with a Logarithmic Function
Let the function $$f(x)=\ln(2+x^2)$$ be differentiable and one-to-one, and let its inverse be $$g(y)
Inverse Function Differentiation with Combined Logarithmic and Exponential Terms
Let $$f(x)=e^{x}+\ln(x)$$ for $$x>1$$ and let g be its inverse function. Answer the following.
Inverse Function Differentiation with Composite Trigonometric Functions
Let $$f(x)= \sin(2*x) + x$$, which is differentiable and one-to-one. It is given that $$f(\pi/6)= 1$
Logarithmic and Exponential Composite Function with Transformation
Let $$g(x)=\ln((3*x+1)^2)-e^{x}$$. Answer the following questions.
Logarithmic Differentiation of a Variable Exponent Function
Consider the function $$y= (x^2+1)^{\sqrt{x}}$$.
Nested Composite Function Differentiation
Consider the function $$ h(x)= \sqrt{\cos(3*x^2+1)} $$.
Rainwater Harvesting System
A rainwater harvesting system collects water in a reservoir. The inflow rate is given by the composi
Analyzing Rate of Approach in a Pursuit Problem
Two cars are traveling on perpendicular roads. Car A is moving east at 60 km/h and is 3 km from the
Chemical Concentration Rate Analysis
The concentration of a chemical in a reactor is given by $$C(t)=\frac{5*t}{t+2}$$ M (moles per liter
Cubic Function with Parameter and Its Inverse
Examine the family of functions given by $$f(x)=x^3+k*x$$, where $$k$$ is a constant.
Deceleration of a Vehicle on a Straight Road
A vehicle travels along a straight road with velocity function $$v(t)=30-4*t$$ (m/s) for $$0 \le t \
Drug Concentration Dynamics
The concentration of a drug in the bloodstream is modeled by $$C(t)= 50*e^{-0.2*t} + 10$$ (in mg/L),
Firework Trajectory Analysis
A firework is launched and its height (in meters) is modeled by the function $$h(t)=-4.9t^2+30t+5$$,
Graphical Analysis of an Inverse Function
Consider a continuously differentiable and strictly increasing function $$f(x)$$ as depicted in the
Industrial Mixer Flow Rates
In an industrial mixer, an ingredient is added at a rate of $$I(t)=7t$$ (kg per minute) and is consu
L'Hôpital's Analysis
Evaluate the limit $$\lim_{x\to\infty}\frac{5*x^3-4*x^2+1}{7*x^3+2*x-6}$$. Answer the following part
Limit Evaluation via L'Hopital's Rule
Evaluate the limit: $$L=\lim_{x\to 0}\frac{e^{2x}-1}{\ln(1+3x)}$$. Answer the following:
Linear Account Growth in Finance
The amount in a savings account during a promotional period is given by the linear function $$A(t)=1
Maclaurin Series for ln(1+x)
Consider the function $$f(x)= \ln(1+x)$$. Its Maclaurin series may be used to approximate values of
Population Decline Modeled by Exponential Decay
A bacteria population is modeled by $$P(t)=200e^{-0.3t}$$, where t is measured in hours. Answer the
Related Rates in a Circular Pool
A circular pool is being filled such that the surface area increases at a constant rate of $$10$$ ft
Revenue Concavity Analysis
A company’s revenue from sales is modeled by the function $$R(x)= 300*x - 2*x^2$$, where \(x\) repre
Sediment Transport in a Riverbank
In a riverbank environment, sediment is deposited at a rate of $$D(t)=20-0.5t$$ (kg/min) while simul
Series Approximation for a Displacement Function
A displacement function is modeled by $$s(t)= \sum_{n=1}^{\infty} \frac{(-1)^{n+1} t^n}{n}$$, which
Series Approximation in Population Dynamics
A population function is given by $$P(t)= 500 \times \sum_{n=0}^{\infty} \frac{(0.03t)^n}{n!}$$. Ans
Vehicle Motion on a Curved Path
A vehicle moving along a straight road has its position given by $$s(t)= 4*t^3 - 24*t^2 + 36*t + 5$$
Water Tank Flow Analysis
A water tank receives water from an inlet at a rate given by $$I(t)=4+\cos(t)$$ (liters per minute)
Amusement Park Ride Braking Distance
An amusement park ride uses a sequence of friction pads to stop a roller coaster. The first pad diss
Analysis of a Motion Function Incorporating a Logarithm
A particle's position is given by $$s(t)= \ln(t+1)+ t$$, where $$t$$ is in seconds. Analyze the moti
Analysis of a Quartic Function as a Perfect Power
Consider the function $$f(x)=x^4-4*x^3+6*x^2-4*x+1$$. Answer the following parts:
Application of Rolle's Theorem
Consider the function $$f(x) = x^2 - 4*x + 4$$ on the interval $$[0,4]$$.
Concavity & Inflection Points for a Rational Polynomial Function
Examine the function $$f(x)= \frac{x}{x^2+1}$$ to determine its concavity and identify any inflectio
Convergence and Series Approximation of a Simple Function
Consider the function defined by the power series $$f(x)=\sum_{n=0}^\infty \frac{(-1)^n}{n+1} * x^n$
Determining the Meeting Point of Two Functions
Consider the functions $$f(x)= e^x$$ and $$g(x)= 3 + \ln(x)$$ representing two different processes.
Evaluating an Improper Integral using Series Expansion
The function $$I(x)=\sum_{n=0}^\infty (-1)^n * \frac{(2*x)^{n}}{n!}$$ converges to a known function.
Expanding Oil Spill - Related Rates
A circular oil spill is expanding such that its area is given by $$A(t) = \pi*[r(t)]^2$$. The radius
Extreme Value Theorem: Finding Global Extrema
Consider the function $$f(x)= x^3-6*x^2+9*x+2$$ on the closed interval $$[0,4]$$. Use the Extreme Va
Function Behavior Analysis
Consider the function \( f(x) = x^4 - 4*x^3 + 6*x^2 - 4*x + 1 \). Answer the following parts:
Lake Ecosystem Nutrient Dynamics
In a lake, nutrients (phosphorus) enter at a rate given by $$N_{in}(t)=5*\sin(t)+10$$ mg/min and are
Linear Approximation of a Radical Function
For the function $$f(x)= \sqrt{x+1}+x$$, find its linear approximation at $$x=3$$ and use it to appr
Loan Amortization with Increasing Payments
A loan of $$20000$$ dollars is to be repaid in equal installments over 10 years. However, the repaym
Mean Value Theorem Application
Let $$f(x)=\ln(x)$$ be defined on the interval $$[1, e^2]$$. Answer the following parts using the Me
Mean Value Theorem in Motion
A car travels along a straight highway with its position given by $$s(t)=4*t^3 - 12*t^2 + 9*t + 5$$
Optimization in Particle Routing
A delivery robot’s distance along its predetermined path is described by $$s(t)=\sin(t)+0.5*t$$, whe
Relative Extrema Using the First Derivative Test
Consider the function $$ f(x)=e^{-x^2}.$$ Answer the following parts:
Series Convergence and Differentiation in Thermodynamics
In a thermodynamic process, the temperature $$T(x)=\sum_{n=0}^\infty \frac{(-2)^n}{n+1} * (x-5)^n$$
Sign Chart Construction from the Derivative
Consider the function $$ f(x)=x^4-4x^3+6x^2.$$ Answer the following parts:
Taylor Series for $$\cos(2*x)$$
Consider the function $$f(x)=\cos(2*x)$$. Construct its 4th degree Maclaurin polynomial, determine t
Taylor Series for $$e^{\sin(x)}$$
Let $$f(x)=e^{\sin(x)}$$. First, obtain the Maclaurin series for $$\sin(x)$$ up to the $$x^3$$ term,
Verifying the Mean Value Theorem
Consider the function $$f(x) = x^3 - 4*x^2 + x + 6$$ defined on the interval [0,4].
Volume of a Solid of Revolution Using the Washer Method
Find the volume of the solid obtained by revolving the region bounded by $$y=\sqrt{x}$$, $$y=\frac{x
Analyzing a Cumulative Distribution Function (CDF)
A chemical reaction has a time-to-completion modeled by the cumulative distribution function $$F(t)=
Antiderivative with an Initial Condition
Given the function $$f(x)=6*x$$, find a function $$F(x)$$ such that $$F'(x)=f(x)$$ and $$F(2)=5$$.
Approximating an Exponential Integral via Riemann Sums
Consider the function $$h(x)=e^{-x}$$ on the interval $$[0,2]$$. A table of values is provided below
Area Estimation with Riemann Sums
A water flow rate function f(x) (in m³/s) is measured at various times. The table below shows the me
Area Under an Even Function Using Symmetry
Consider the function $$f(x)=\cos(x)$$ on the interval $$\left[-\frac{\pi}{2}, \frac{\pi}{2}\right]
Cost and Inverse Demand in Economics
Consider the cost function representing market demand: $$f(x)= x^2 + 4$$ for $$x\ge0$$. Answer the f
Cyclist's Distance Accumulation Function
A cyclist’s total distance traveled is modeled by $$D(t)= \int_{0}^{t} (5+\sin(u))\, du + 2$$ kilom
Definite Integration of a Polynomial Function
For the function $$f(x)=5*x^{3}$$ defined on the interval $$[1,2]$$, determine the antiderivative an
Determining Antiderivatives and Initial Value Problems
Suppose that $$F(x)$$ is an antiderivative of the function $$f(x)=5*x^4 - 2*x + 3$$, and that it is
Displacement vs. Total Distance Traveled
A particle moves along a straight line with the velocity function given by $$v(t)=t^2 - 4*t + 3$$. O
Distance from Acceleration Data
A car's acceleration is recorded in the table below. Given that the initial velocity is $$v(0)= 10$$
Estimating Area Under a Curve from Tabular Data
A function $$f(t)$$ is sampled at discrete time points as given in the table below. Using these data
Estimating Chemical Production via Riemann Sums
In a laboratory experiment, the reaction rate of a chemical process is recorded at various times. Th
Estimating Rainfall Accumulation
Rainfall intensity measurements (in mm/hr) at various times are recorded in the table. Use Riemann s
Fuel Consumption Estimation with Midpoint Riemann Sums
A vehicle’s fuel consumption rate (in liters per hour) over a trip is recorded at various times. The
Graphical Transformations and Inverse Functions
Consider the linear function $$f(x)= \frac{1}{2}*x + 5$$ defined for all real $$x$$. Answer the foll
Improper Integral and the p-Test
Determine whether the improper integral $$\int_1^{\infty} \frac{1}{x^2}\,dx$$ converges, and if it c
Integration by U-Substitution and Evaluation of a Definite Integral
Evaluate the definite integral $$\int_{0}^{1} \frac{2*t}{(t^2+1)^2}\, dt$$ by applying U-substitut
Integration Involving Trigonometric Functions
Evaluate the definite integral $$\int_{0}^{\frac{\pi}{2}} \cos(2*t)\,dt.$$
Integration of a Trigonometric Product via U-Substitution
Evaluate the indefinite integral $$\int \sin(2*x)\cos(2*x)\,dx$$.
Parameter-Dependent Integral Function Analysis
Define the function $$F(x)=\int_(1)^(x) \frac{\ln(t)}{t} dt$$ for x > 1. This function accumulates t
Particle Motion with Variable Acceleration and Displacement Analysis
A particle moves along a straight line with acceleration given by $$a(t)=4-2*t$$ (in m/s²). At time
Population Growth from Birth Rate
In a small town, the birth rate is modeled by $$B(t)= \frac{100}{1+t^2}$$ people per year, where $$t
Rainfall Accumulation Over Time
A storm produces rainfall at a rate modeled by the function $$r(t)=6 * t^(1/2)$$, where $$0 \le t \l
Recovering Accumulated Change
A company’s revenue rate changes according to $$R'(t)=8*t-12$$ (in dollars per day). If the revenue
Reservoir Water Level
A reservoir experiences a net water inflow modeled by $$W(t)=40*\sin\left(\frac{\pi*t}{12}\right)-5$
Rocket Height Determination via U-Substitution
A rocket’s velocity is modeled by the function $$v(t)=t * e^(t^(2))$$ (in m/s) for $$t \ge 0$$. With
Series Representation and Term Operations
Consider the power series for $$\arctan(x)$$ given by $$\sum_{n=0}^\infty (-1)^n \frac{x^{2n+1}}{2n+
Temperature Change Analysis
A series of temperature readings (in °C) are recorded over the day as shown in the table. Analyze th
Total Work Done by a Variable Force
A variable force $$F(x)$$ (in Newtons) is applied along a displacement, and its values are recorded
Vehicle Motion and Inverse Time Function
A vehicle’s displacement (in meters) is modeled by the function $$f(t)= t^2 + 4$$ for $$t \ge 0$$ se
Volume by Cross-Section: Squares on a Parabolic Base
A solid has a base in the xy-plane bounded by the curves $$y=x^2$$ and $$y=4$$. Cross-sections perpe
Volume of a Solid: Cross-Sectional Area
A solid has cross-sectional area perpendicular to the x-axis given by $$A(x)= (4-x)^2$$ for $$0 \le
Capacitor Charging with Leakage
A capacitor is being charged by a constant current source of $$5$$ A, but it also leaks charge at a
Chemical Reactor Mixing
In a chemical reactor, the concentration $$C(t)$$ (in M) of a chemical is governed by the equation $
Compound Interest and Investment Growth
An investment account grows according to the differential equation $$\frac{dA}{dt}=r*A$$, where the
Compound Interest with Continuous Payment
An investment account grows with a continuous compound interest rate $$r$$ and also receives continu
Cooling Model Using Newton's Law
Newton's law of cooling states that the temperature T of an object changes at a rate proportional to
Economic Model: Differential Equation for Cost Function
A company’s marginal cost is represented by $$MC(x)=\frac{dC}{dx}=3+2*x$$, where $$x$$ is the number
Estimating Instantaneous Rate from a Table
A function $$f(x)$$ is defined by the following table of values:
Exact Differential Equation
Consider the differential equation $$ (2*x*y + y^2)\,dx + (x^2+2*x*y)\,dy = 0 $$. Answer the followi
Exact Differential Equation
Examine the differential equation $$ (2*x*y + y^2)\,dx + (x^2 + 2*x*y)\,dy = 0 $$. Determine if the
Exact Differential Equations and Integrating Factors
Consider the differential equation $$ (2*x*y + y^2)\,dx + (x^2 + 2*x*y - 1)\,dy = 0$$. Answer the fo
Exponential Growth and Decay
A bacterial population grows according to the differential equation $$\frac{dy}{dt}=k\,y$$ with an i
Forced Oscillation in a Damped System
Consider the differential equation $$\frac{dx}{dt}=-0.2*x+\sin(t)$$ with initial condition $$x(0)=1$
FRQ 3: Population Growth and Logistic Model
A population $$P(t)$$ grows according to the logistic differential equation $$\frac{dP}{dt} = k*P\le
FRQ 7: Projectile Motion with Air Resistance
A projectile is launched vertically upward with an initial velocity of 50 m/s. Its vertical motion i
FRQ 9: Epidemiological Model Differential Equation
An epidemic evolves according to the differential equation $$\frac{dI}{dt}=r*I*(M-I)$$, where $$I(t)
FRQ 11: Linear Differential Equation via Integrating Factor
Solve the differential equation $$\frac{dy}{dx}+\frac{1}{x}y=\sin(x)$$ with the initial condition $$
Logistic Growth Model
A population P grows according to the logistic differential equation $$\frac{dP}{dt} = rP\left(1-\fr
Mixing Problem in a Tank
A tank initially contains a certain amount of salt dissolved in 100 L of water. Brine with a known s
Modeling Cooling in a Variable Environment
Suppose the cooling of a heated object is modeled by the differential equation $$\frac{dT}{dt} = -k*
Newton's Law of Cooling
An object cools according to Newton's Law of Cooling: $$\frac{dT}{dt} = -k*(T-20)$$, where the ambie
Optimization in Construction: Minimizing Material for a Container
A manufacturer is designing an open-top cylindrical container with fixed volume $$V$$. The material
Particle Motion with Damping
A particle moving along a straight line is subject to damping and its motion is modeled by the secon
Projectile Motion with Air Resistance
A projectile is fired vertically upward with an initial velocity of $$50\,m/s$$. The projectile expe
Radioactive Decay
A radioactive substance decays according to the differential equation $$\frac{dA}{dt}=-kA$$, where $
Reservoir Contaminant Dilution
A reservoir has a constant volume of 10,000 L and contains a pollutant with amount $$Q(t)$$ (in kg)
Salt Tank Mixing Problem
A tank contains $$100$$ L of water with $$10$$ kg of salt. Brine containing $$0.5$$ kg of salt per l
Separable Differential Equation with a Logarithmic Integral
Consider the differential equation $$\frac{dy}{dx}=\frac{x}{y+1}$$ with the initial condition $$y(1)
Slope Field and Solution Curve Sketching
Consider the differential equation $$\frac{dy}{dx} = x - 1$$. A slope field for this differential eq
Temperature Control in a Chemical Reaction Vessel
In a chemical reactor, the temperature $$T(t)$$ is regulated by both natural cooling and an external
Area Between a Parabola and a Line
Consider the region bounded by the curves $$y=5*x - x^2$$ and $$y=x$$ where they intersect. Answer t
Area Between Curves in a Business Context
A company’s revenue and cost (in dollars) for producing items (in hundreds) are modeled by the funct
Area Between Curves: Supply and Demand Analysis
In an economic model, the supply and demand functions for a product (in hundreds of units) are given
Area Between Exponential Curves
Consider the functions $$f(x)=e^{-x}$$ and $$g(x)=e^{-2*x}$$ for $$x\ge0$$. Answer the following:
Area Between Two Curves: Parabola and Line
Consider the functions $$f(x)= 5*x - x^2$$ and $$g(x)= x$$. These curves enclose a region in the pla
Area of One Petal of a Polar Curve
The polar curve defined by $$r = \cos(2\theta)$$ forms a rose with four petals. Find the area of one
Average and Instantaneous Analysis in Periodic Motion
A particle moves along a line with its displacement given by $$s(t)= 4*\cos(2*t)$$ (in meters) for $
Average Chemical Concentration Analysis
In a chemical reaction, the concentration of a reactant (in M) is recorded over time as given in the
Average Fuel Consumption and Optimization
A vehicle's fuel consumption rate is modeled by the function $$f(x)=2*x^2-8*x+10$$, where $$x$$ repr
Average Population Density on a Road
A town's population density along a road is modeled by the function $$P(x)=50*e^{-0.1*x}$$ (persons
Average Reaction Concentration in a Chemical Reaction
In a chemical reaction, the concentration of a reactant is modeled by $$C(t)=20*\exp(-0.5*t)$$ (in m
Average Velocity and Displacement from a Polynomial Function
A car's velocity in m/s is given by $$v(t)=t^2-4*t+3$$ for $$t\in[0,5]$$ seconds. Answer the followi
Center of Mass of a Rod with Variable Density
A rod extending along the x-axis from $$x=0$$ to $$x=10$$ meters has a density given by $$\rho(x)=2+
Complex Integral Evaluation with Exponential Function
Evaluate the integral $$I=\int_1^e \frac{2*\ln(t)}{t}dt$$ by applying a suitable substitution.
Determining the Arc Length of a Curve
Consider the curve defined by $$y=\frac{1}{2}*e^{x/2}$$ over the interval $$[0,2]$$.
Displacement from a Velocity Graph
A runner’s velocity is given by $$v(t)=8-0.5*t$$ (m/s) for $$0\le t\le 12$$ seconds. A graph of this
Distance Traveled versus Displacement
A particle moves along a line with velocity given by $$v(t)=t^3 - 6*t^2 + 9*t$$ (in m/s) for $$t\in[
Implicit Function Differentiation
Consider the implicitly defined function $$\sin(x * y) + x^2 = \ln(y)$$. Answer the following:
Moment of Inertia of a Thin Plate
A thin plate occupies the region bounded by the curves $$y= x$$ and $$y= x^2$$ for $$0 \le x \le 1$$
Particle Motion from Acceleration
A particle has an acceleration given by $$a(t)=3*t-6$$ (m/s²). With initial conditions $$v(0)=2$$ m/
Polar Coordinates: Area of a Region
A region in the plane is described in polar coordinates by the equation $$r= 2+ \cos(θ)$$. Determine
Shadow Length Related Rates
A 1.8-meter tall man is walking away from a 5-meter tall lamp post at a constant speed of $$1.5$$ m/
Total Change in Temperature Over Time (Improper Integral)
An object cools according to the function $$\Delta T(t) = e^{-0.5*t}$$, where $$t\ge 0$$ is time in
Volume by Shell Method: Rotating a Region
Consider the region bounded by the curves $$y=x$$ and $$y=x^2$$. This region is rotated about the y-
Volume of a Solid of Revolution Between Curves
Consider the region bounded by the curves $$y=\sqrt{x}$$ and $$y=\frac{x}{2}$$ for $$x \in [0,4]$$.
Volume of a Solid Using the Shell Method
The region in the first quadrant bounded by $$y=x$$, $$y=0$$, and $$x=4$$ is rotated about the y-axi
Volume of a Solid via Shell Method
Consider the region bounded by $$y=x^2$$ and $$y=4$$ in the first quadrant. This region is revolved
Volume of a Solid: ln(x) Region Rotated
Consider the region in the $$xy$$-plane bounded by $$y=\ln(x)$$, $$y=0$$, $$x=1$$, and $$x=e$$. This
Volume with Equilateral Triangle Cross Sections
The region bounded by $$y=4-x^2$$ and $$y=0$$ for $$x\in[-2,2]$$ serves as the base of a solid. Cros
Work Done by a Variable Force
A variable force given by $$F(x)= 2*x + 3$$ (in Newtons) is applied to an object as it moves along a
Work Done by a Variable Force
A variable force acting along the x-axis is given by $$F(x) = 2 * x + 3$$ (in Newtons). An object mo
Analyzing a Walker's Path: A Vector-Valued Function
A pedestrian's path is modeled by the vector function $$\vec{r}(t)= \langle t^2 - 4, \sqrt{t+5} \ran
Arc Length of a Parametric Curve
The curve defined by $$x(t)=\ln(t+1)$$ and $$y(t)=\sqrt{t}$$ for $$t \in [0,4]$$ is given.
Arc Length of a Parametric Curve
Consider the curve defined by the parametric equations $$x(t)=3*\cos(t)$$ and $$y(t)=3*\sin(t)$$ for
Area Between Polar Curves
In the polar coordinate plane, consider the region bounded by the curves $$r = 2 + \cos(\theta)$$ (t
Area between Two Polar Curves
Given two polar curves: $$r_1 = 1+\cos(\theta)$$ and $$r_2 = 2\cos(\theta)$$, consider the region wh
Average Position from a Vector-Valued Function
A particle moves in the plane according to the vector function $$\mathbf{r}(t)=\langle \sin(t), \cos
Conversion and Differentiation of a Polar Curve
Consider the polar curve defined by $$ r=2+\sin(\theta) $$. Study its conversion to Cartesian coordi
Conversion from Polar to Cartesian Coordinates
The polar equation $$r(\theta)=4*\cos(\theta)$$ represents a curve.
Conversion of Parametric to Polar: Motion Analysis
An object moves along a path given by the parametric equations $$x(t)=t^2$$ and $$y(t)=2*t$$ for $$t
Converting Polar to Cartesian and Computing Slope
The polar curve is given by the equation $$r=4\cos(\theta)$$. Answer the following:
Designing a Race Track with Parametric Equations
An engineer designs a race track whose left and right boundaries are described by the curves $$C_1:
Differentiability of a Piecewise-Defined Vector Function
Consider the vector-valued function $$\textbf{r}(t)= \begin{cases} \langle t, t^2 \rangle & \text{i
Exponential and Logarithmic Dynamics in a Polar Equation
Consider the polar curve defined by $$r=e^{\theta}$$. Answer the following:
Exponential Growth in Parametric Representation
A model for population growth is given by the parametric equations $$x(t)=t$$ and $$y(t)=e^{0.3t}$$,
Finding the Slope of a Tangent to a Parametric Curve
Consider the parametric equations $$x(t)=e^t$$ and $$y(t)=e^{-t}$$, where $$t \in \mathbb{R}$$.
Implicit Differentiation with Implicitly Defined Function
Consider the equation $$x^2+xy+y^2=7$$, which defines $$y$$ implicitly as a function of $$x$$.
Integration of Vector-Valued Acceleration
A particle's acceleration is given by the vector function $$\mathbf{a}(t)=\langle 2*t,\; 6-3*t \rang
Kinematics in Polar Coordinates
An object moves so that its position in polar coordinates is given by $$r(t)= 4 - t$$ and $$\theta(t
Modeling Projectile Motion with Parametric Equations
A projectile is launched with an initial speed of \(20\) m/s at an angle of \(45^\circ\) above the h
Numerical Integration Techniques for a Parametric Curve
A curve is defined by the parametric equations $$x(t)=\ln(t+1)$$ and $$y(t)=\sqrt{t}$$ for $$0 \le t
Parameter Elimination in Logarithmic and Quadratic Relationships
Given the parametric equations $$x(t)= \ln(t)$$ and $$y(t)= t^2 - 4*t + 3$$ for $$t > 0$$, eliminate
Parametric Curve with a Loop and Tangent Analysis
Consider the parametric curve defined by $$x(t)=t^3-3*t$$ and $$y(t)=t^2$$, where $$t\in[-2,2]$$. An
Parametric Representation of Circular Motion
An object moves along a circle of radius $$5$$, with its position given by $$x(t)=5\cos(t)$$ and $$y
Parametric Spiral Curve Analysis
The curve defined by $$x(t)=t\cos(t)$$ and $$y(t)=t\sin(t)$$ for $$t \in [0,4\pi]$$ represents a spi
Polar Spiral: Area and Arc Length
Consider the polar spiral defined by $$r(\theta)=1+\frac{\theta}{2}$$ for $$0\le\theta\le 2\pi$$. An
Sensitivity Analysis and Linear Approximation using Implicit Differentiation
The variables $$x$$ and $$y$$ satisfy the equation $$xy+\ln(y)=5$$.
Spiral Motion in Polar Coordinates
A particle moves in polar coordinates with \(r(\theta)=4-\theta\) and the angle is related to time b
Vector-Valued Functions and Curvature
Let the vector-valued function be $$\vec{r}(t)= \langle t, t^2, t^3 \rangle$$.
Vector-Valued Functions: Position, Velocity, and Acceleration
Let $$\textbf{r}(t)= \langle e^t, \ln(t+1) \rangle$$ represent the position of a particle in the pla
Vector-Valued Motion: Acceleration and Maximum Speed
A particle's position is given by the vector function $$\vec{r}(t)=\langle t e^{-t}, \ln(t+1) \rangl
Velocity and Acceleration of a Particle
A particle’s position in three-dimensional space is given by the vector-valued function $$\mathbf{r}
Work Done by a Force along a Path
A force acting on an object is given by the vector function $$\vec{F}(t)= \langle 3t,\; 2,\; t^2 \ra
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