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Analyzing Discontinuities in a Piecewise Function
Consider the function $$f(x)= \begin{cases}\frac{x^2-1}{x-1}, & x \neq 1 \\ 3, & x=1\end{cases}$$.
Analyzing Limits of a Composite Function
Let $$f(x)=\frac{\sin(\sqrt{4+x}-2)}{x}$$ for $$x \neq 0$$. Answer the following:
Calculating Tangent Line from Data
The table below gives a function $$f(x)$$ representing the distance (in meters) of a moving object f
Continuity in Piecewise Functions with Parameters
A function is defined piecewise by $$f(x)=\begin{cases}a*x^2+3,& x<1,\\ b*x+1,& x\ge 1.\end{cases}$$
Establishing Continuity in a Piecewise Function
Consider the piecewise-defined function $$p(x)= \begin{cases} \frac{x^2-4}{x-2} & x \neq 2, \\ k & x
Evaluating a Limit with Algebraic Manipulation
Examine the function $$g(x)= \frac{\sqrt{x+9}-3}{x}$$ for $$x \neq 0$$.
Experimental Data Limit Estimation from a Table
Using the table below, estimate the behavior of a function f(x) as x approaches 1.
Fuel Efficiency and Speed Graph Analysis
A car manufacturer records data on fuel efficiency (in mpg) as a function of speed (in mph). A graph
Graphical Analysis of a Continuous Polynomial Function
Consider the function $$f(x)=2*x^3-5*x^2+x-7$$ and its graph depicted below. The graph provided accu
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
Investigating Limits and Areas Under Curves
Consider the region bounded by the curve $$y=\frac{1}{x}$$, the vertical line $$x=1$$, and the verti
Investigating Limits at Infinity and Asymptotic Behavior
Given the rational function $$f(x)=\frac{5*x^2-3*x+2}{2*x^2+x-1}$$, answer the following: (a) Evalua
Limits Involving Absolute Value Functions
Consider the function $$f(x)=\frac{|x-3|}{x-3}$$. Answer the following:
Limits via Improper Integration Representation
Consider the function defined by the integral $$f(x)= \int_{1}^{x} \frac{1}{t^2} dt$$ for x > 1. Add
Limits with a Parameter in a Trigonometric Function
Consider the function $$f(x)= \begin{cases} \frac{\sin(a*x)}{x} & x \neq 0 \\ b & x=0 \end{cases}$$,
Logarithmic Function Limits
Consider the function $$f(x)=\frac{\ln(1+3*x)}{x}$$ for $$x \neq 0$$. Answer the following:
Piecewise Function Continuity
Consider the function defined by $$ f(x)=\begin{cases} \frac{x^2-4}{x-2}, & x\neq2\\ k, & x=2 \en
Seasonal Temperature Curve Analysis
A graph represents the average daily temperature (in $$^\circ C$$) as a function of the day of the y
Series Representation and Convergence Analysis
Consider the power series $$S(x)=\sum_{n=1}^{\infty} \frac{(-1)^{n+1}*(x-2)^n}{n}.$$ (Calculator per
Water Tank Flow Analysis
A water tank receives water from an inlet and drains water through an outlet. The inflow rate is giv
Analyzing a Function with an Oscillatory Component
Consider the function $$f(x)= x*\sin(x)$$. Answer the following:
Applying Product and Quotient Rules
For the function $$h(x)=\frac{(3*x^2+2)*(x-4)}{x+1}$$, determine its derivative by appropriately app
Car Acceleration: Secant and Tangent Slope
A car's position along a straight road is given by $$s(t)= 2t^3 - 9t^2 + 12t$$, where s is in meters
Cooling Model Rate Analysis
The temperature of a cooling object is modeled by $$T(t)=e^{-2*t}+\ln(t+3)$$, where $$t$$ is time in
Derivative Using Limit Definition
Let $$f(x)=\frac{1}{x+2}$$. Using the definition of the derivative, find $$f'(x)$$.
Derivatives of Inverse Functions
Let $$f(x)=\ln(x)$$ with inverse function $$f^{-1}(x)=e^x$$. Answer the following parts.
Differentiation in Biological Growth Models
In a biological experiment, the rate of resource consumption is modeled by $$R(t)=\frac{\ln(t^2+1)}{
Differentiation of a Rational Function
Consider the function $$f(x) = \frac{2*x^2+3*x}{x-1}$$, which is defined on its domain. Analyze the
Engineering Analysis of Log-Exponential Function
In an engineering system, the output voltage is given by $$V(x)=\ln(4*x+1)*e^{-0.5*x}$$, where $$x$$
Epidemiological Rate Change Analysis
In epidemiology, the spread of a disease is sometimes modeled by a combination of logarithmic and ex
Error Bound Analysis for $$e^{2x}$$
In a study of reaction rates, the function $$f(x)=e^{2*x}$$ is used. Analyze the error in approximat
Graphical Derivative Analysis
A series of experiments produced the following data for a function $$f(x)$$:
Implicit Differentiation for a Rational Equation
Consider the curve defined by $$\frac{x*y}{x+y} = 3$$.
Implicit Differentiation with Inverse Functions
Suppose a differentiable function $$f$$ satisfies the equation $$f(x) + f^(-1)(x) = 2*x$$ for all x
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
Logarithmic Differentiation
Let $$T(x)= (x^2+1)^{3*x}$$ model a quantity with variable growth characteristics. Use logarithmic d
Optimization in Engineering Design
A manufacturer designs a cylindrical can with a fixed volume of $$1000\,cm^3$$. The surface area of
Optimization Using Derivatives
Consider the quadratic function $$f(x)=-x^2+4*x+5$$. Answer the following:
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
Renewable Energy Storage
A battery storage system experiences charging at a rate of $$C(t)=50+10\sin(0.5*t)$$ kWh and dischar
Satellite Orbit Altitude Modeling
A satellite’s altitude (in kilometers) above Earth is modeled by $$a(t)= 500*\cos\left(\frac{\pi}{6}
Tangent and Normal Lines to a Curve
Given the function $$p(x)=\ln(x)$$ defined for $$x > 0$$, analyze its rate of change at a specific p
Tangent Line to a Logarithmic Function
Consider the function $$f(x)= \ln(x+1)$$.
Using the Product Rule in Economics
A company’s revenue function is given by $$R(x)=x*(100-x)$$, where $$x$$ (in hundreds) represents th
Chain Rule and Implicit Differentiation in a Pendulum Oscillation Experiment
In a pendulum experiment, the angle \(\theta(t)\) in radians satisfies the relation $$\cos(\theta(t)
Chain Rule Combined with Inverse Trigonometric Differentiation
Let $$h(x)= \arccos((2*x-1)^2)$$. Answer the following:
Composite and Inverse Differentiation in an Electrical Circuit
In an electrical circuit, the current is modeled by $$ I(t)= \sqrt{20*t+5} $$ and the voltage is giv
Composite Differentiation in Biological Growth
A biologist models the temperature $$T$$ (in °C) of a culture over time $$t$$ (in hours) by the func
Composite Function Analysis
Consider the function $$f(x)= \sqrt{3*x^2+2*x+1}$$ which arises in an experimental study of motion.
Composite Function Modeling with Chain Rule
A chemical reaction rate is modeled by the composite function $$R(x)=f(g(x))$$ where $$f(u)=\sin(u)$
Composite Function with Implicitly Defined Inner Function
Let the function $$h(x)$$ be defined implicitly by the equation $$h(x) - \ln(h(x)) = x$$, and consid
Composite Functions in Biological Growth
Let a model for bacteria growth be represented by $$f(t)=e^{2*t}$$, and let the effect of nutrient c
Differentiation of an Inverse Trigonometric Function
Define $$h(x)= \arctan(\sqrt{x})$$. Answer the following:
Graphical Analysis of a Composite Function
Let $$f(x)=\ln(4*e^{x}+1)$$. A graph of f is provided. Answer the following parts.
Higher Order Implicit Differentiation in a Nonlinear Model
Assume that \(x\) and \(y\) are related by the nonlinear equation $$e^{x*y} + x - \ln(y) = 5$$ with
Implicit Differentiation in a Conic Section
Consider the curve defined by $$x^2 + x*y + y^2 = 9$$.
Implicit Differentiation in a Non-Standard Function
Consider the equation $$x^2*y + \sin(y) = x$$, which implicitly defines $$y$$ as a function of $$x$$
Implicit Differentiation Involving Logarithms
Consider the equation $$\ln(x+y)=x*y$$ which relates x and y. Answer the following parts:
Implicit Differentiation with Exponential and Trigonometric Components
Consider the relation $$ (x^2 + y^2) * e^{y} = x $$. Answer the following:
Inverse Analysis via Implicit Differentiation for a Transcendental Equation
Consider the equation $$e^{x*y}+x-y=0$$ defining y implicitly as a function of x near a point where
Inverse Differentiation of a Trigonometric Function
Consider the function $$f(x)=\arctan(2*x)$$ defined for all real numbers. Analyze its inverse functi
Inverse Function Analysis for Exponential Functions
Let $$f(x)=e^{2*x}+1$$ and let g be the inverse function of f. Answer the following parts.
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 for a Cubic Function
Let $$f(x)= x^3 + x$$ be an invertible function with inverse $$g(x)$$. Use the inverse function deri
Inverse Function Differentiation in a Trigonometric Context
Let $$f(x)= \sin(x) + x$$, defined on the interval $$[0, \frac{\pi}{2}]$$, and let $$g$$ be its inve
Inverse Function Differentiation in Thermodynamics
In a thermodynamics experiment, a differentiable one-to-one function $$f$$ describes the temperature
Inverse Function in Logistic Population Growth
A population model is given by $$P(t)=\frac{100}{1+4e^{-0.5*t}}$$ for t \ge 0. Analyze the inverse f
Inverse of a Piecewise Function
Consider the piecewise function $$f(x)=\begin{cases} x^2 & x \ge 0 \\ -x & x < 0 \end{cases}$$. Anal
Inverse of a Shifted Logarithmic Function
Analyze the function $$f(x)=\ln(x-1)+2$$ defined for $$x>1$$ and its inverse.
Inverse Trigonometric Functions in Navigation
A ship navigates such that its angular position relative to a fixed reference is given by $$\theta =
Navigation on a Curved Path: Boat's Eastward Velocity
A boat's location in polar coordinates is described by $$r(t)= \sqrt{4*t+1}$$ and its direction by $
Projectile Motion and Composite Exponential Functions
A projectile’s height at time $$t$$ (in seconds) is modeled by the function $$h(t)= e^{- (t-2)^2}$$.
Reservoir Level: Inverse Function Application
A reservoir's water level $$h$$ (in feet) is related to time $$t$$ (in minutes) through an invertibl
Second Derivative via Implicit Differentiation
Given the relation $$x^2 + x*y + y^2 = 7$$, answer the following:
Taylor Polynomial and Error Bound for a Trigonometric Function
Let $$f(x) = \cos(2*x)$$. Develop a second-degree Taylor polynomial centered at 0, and analyze the a
Temperature Control: Heating Element Dynamics
A room's temperature is controlled by a heater whose output is given by the composite function $$H(t
Biological Growth Rate
A bacterial culture grows according to the model $$P(t)= 500*e^{0.8*t}$$, where \(P(t)\) is the popu
Concavity and Acceleration in Motion
A car’s position is modeled by $$s(t)= t^3 - 6*t^2 + 9*t+5$$ with time $$t$$ in seconds. Analyze the
Cooling Coffee: Temperature Change
The temperature of a cup of coffee is modeled by $$T(t)=70+50*e^{-0.1*t}$$, where $$T$$ is in degree
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),
Estimation Error with Differentials
Let $$f(x)=x^3$$. Use differentials to estimate the value of $$f(2.05)$$ and determine the approxima
Implicit Differentiation: Tangent to a Circle
Consider the circle given by $$x^2 + y^2 = 25$$.
Inflating Balloon: Radius and Surface Area
A spherical balloon is being inflated such that its volume increases at a constant rate of 12 cm³/s.
Instantaneous vs. Average Speed in a Race
An athlete’s displacement during a 100 m race is modeled by $$s(t)=2*t^3-t^2+1$$, where $$s(t)$$ is
L'Hospital's Rule in Indeterminate Form Computation
Evaluate the limit $$\lim_{x\to \infty}\frac{5*x^3-4*x^2+1}{7*x^3+2*x-6}$$.
Linearization to Estimate Change in Electrical Resistance
The resistance of a wire is modeled by $$R(T)=R_0(1+\alpha*T)$$, where $$R_0=100$$ ohms and $$\alpha
Logarithmic Function Series Analysis
The function $$L(x)= \sum_{n=1}^{\infty} \frac{(-1)^{n+1}(x-1)^n}{n}$$ represents $$\ln(x)$$ centere
Optimization with Material Costs
A company plans to design an open-top rectangular box with a square base that must have a volume of
Piecewise Velocity and Acceleration Analysis
A particle moves along a straight line with its velocity given by $$ v(t)= \begin{cases} t^2-4*t+3,
Pollution Decay and Inversion
A model for pollution decay is given by the function $$f(t)=\frac{100}{1+t}$$ where $$t\ge0$$ repres
Projectile Motion Analysis
A projectile is launched such that its horizontal and vertical positions are modeled by the parametr
Related Rates: Inflating Spherical Balloon
A spherical balloon is being inflated so that its volume, given by $$V= \frac{4}{3}\pi*r^3$$, increa
Related Rates: Inflating Spherical Balloon with Exponential Volume Rate
A spherical balloon is being inflated so that its volume changes at a rate of $$\frac{dV}{dt}=8e^{0.
Security Camera Angle Change
A security camera is mounted on a 15 m tall tower. Let $$x$$ denote the horizontal distance from the
Series Analysis in Profit Optimization
A company's profit function near a break-even point is approximated by $$\pi(x)= 1000 + \sum_{n=1}^{
Series Integration for Work Calculation
A force along a displacement is given by $$F(x)= \sum_{n=0}^{\infty} \frac{(-1)^n x^n}{n+2}$$ (in Ne
Water Filtration Plant Analysis
A water filtration plant processes water entering at a rate of $$I(t)=60-2t$$ (liters per minute) an
Analysis of Relative Extrema and Increasing/Decreasing Intervals
A particle moves along a line with position given by $$s(x)=x^3-6*x^2+9*x+4$$, where $$x$$ represent
Average and Instantaneous Velocity Analysis
A bird’s position is given by $$s(t)=2*t^2-t+1$$ (in meters) for $$t\in[0,3]$$ seconds.
Car Depreciation Analysis
A new car is purchased for $$30000$$ dollars. Its value depreciates by 15% each year. Analyze the de
Chemical Reaction Rate
During a chemical reaction, the concentration of a reagent (in M) is measured over time (in minutes)
Concavity Analysis of a Population Growth Model
A biologist models a species’ population (in thousands) with the function $$f(x) = x^3 - 9*x^2 + 24*
Concavity and Inflection Points
Let $$f(x)=x^3-6x^2+9x+2.$$ Answer the following parts:
Concavity and Inflection Points
Examine the function $$p(x)= x^3-3*x^2-9*x+30$$ to determine its concavity and any inflection points
Determining Absolute Extrema for a Trigonometric-Polynomial Function
Consider the function $$f(x)= x+\cos(x)$$ defined on the closed interval $$[0, 2\pi]$$. Determine th
Determining Absolute Extrema in a Motion Context
A particle’s position is modeled by $$s(t)=-t^3+6*t^2-9*t+2$$, where $$t\in[0,5]$$ seconds.
Determining Convergence and Error Analysis in a Logarithmic Series
Investigate the series $$L(x)=\sum_{n=1}^\infty (-1)^{n+1} * \frac{(x-1)^n}{n}$$, which represents a
Exponential Decay in Velocity
A particle’s velocity is modeled by the function $$v(t)=10e^{-0.5*t}-3$$ (in m/s) for $$t\ge0$$.
Extreme Value Analysis of a Logarithmic-Exponential-Polynomial Function
Examine the function $$f(x)= x^2\,e^{-x} + \ln(x)$$ defined for $$x > 0$$. Apply methods to find its
Inverse Function and Critical Points in a Business Context
A company models its profit (in thousands of dollars) by $$f(x)= \ln(4*x+7)$$ for $$x \ge 0$$, where
Investigating a Composite Function Involving Logarithms and Exponentials
Let $$f(x)= \ln(e^x + x^2)$$. Analyze the function by addressing the following parts:
Loan Amortization with Increasing Payments
A loan of $$20000$$ dollars is to be repaid in equal installments over 10 years. However, the repaym
Mean Value Theorem Application
Let \( f(x) = x^3 - 3*x^2 + 2 \) be defined on the closed interval \([0,3]\). Answer the following p
Mean Value Theorem with Trigonometric Function
Consider the function $$f(x)= \sin(x)$$ on the interval $$[0,\pi]$$.
Optimizing Fencing for a Field
A farmer has $$100$$ meters of fencing to construct a rectangular field that borders a river (no fen
Rolle's Theorem on a Cubic Function
Consider the cubic function $$f(x)= x^3-3*x^2+2*x$$ defined on the interval $$[0,2]$$. Verify that t
Stress Analysis in Engineering Structures
A beam experiences stress along its length given by $$S(x)=5*x^3-30*x^2+45*x$$ where x is the distan
Tangent Line and Linearization
Consider the function $$ f(x)=\sqrt{x+5}.$$ Answer the following parts:
Taylor Series for $$\sqrt{1+x}$$
Consider the function $$f(x)=\sqrt{1+x}$$. In this problem, compute its 3rd degree Maclaurin polynom
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,
Temperature Change in a Weather Balloon
A weather balloon’s temperature and altitude are related by the implicit equation $$T*e^{z} + z = 50
Vector Analysis of Particle Motion
A particle moves in the plane with its position given by the vector function $$\mathbf{r}(t) = \lang
Accumulation Function in an Investment Model
An investment has an instantaneous rate of return given by $$r(t)=0.05*t+0.02$$ (per year). The accu
Antiderivative with Initial Condition
Find the general antiderivative of the function $$f(x)=5*x^3-2*x+6$$ and determine the particular an
Antiderivatives and the Constant of Integration
Consider the rate function $$ r(t)= 2*t + 3 $$ where t represents time in seconds.
Applying the Fundamental Theorem of Calculus
Consider the function $$f(x)=2*x$$. Use the Fundamental Theorem of Calculus to evaluate the definite
Area and Volume of a Region Bounded by Trigonometric Functions
Consider the curves $$y=\sin(x)$$ and $$y=\cos(x)$$ for $$0 \le x \le \frac{\pi}{4}$$. Answer the fo
Area Under a Parametric Curve
Consider the parametric curve defined by $$x(t)=t$$ and $$y(t)=t^2$$ for $$t \in [0,3]$$. The area u
Biomedical Modeling: Drug Concentration Dynamics
A drug concentration in the bloodstream is modeled by $$f(t)= 5\left(1 - e^{-0.3*t}\right)$$ for $$t
Continuity and Integration of a Sinc-like Function
Consider the function $$ f(x)= \begin{cases} \frac{\sin(x)}{x} & \text{if } x \neq 0, \\ 1 & \text{i
Drug Concentration in a Bloodstream
A patient receives an intravenous drug infusion at a rate $$R_{in}(t)=3e^{-0.1*t}$$ mg/min for $$0 \
Economic Applications: Consumer and Producer Surplus
In a market, the demand function is given by $$D(p)=100-2p$$ and the supply function by $$S(p)=20+3p
Error Analysis in Riemann Sum Approximations
Consider approximating the integral $$\int_{0}^{2} x^3\,dx$$ using a left-hand Riemann sum with $$n$
Error Estimation in Riemann Sum Approximations
Consider the function $$f(x)=\sqrt{x}$$ on the interval $$[1,9]$$. When approximating the definite i
Estimating Area Under a Curve Using Riemann Sums
A function $$f(x)$$ is defined on the interval $$[0,6]$$. The following table provides the values of
Evaluating an Integral Involving an Exponential Function
Evaluate the definite integral $$\int_{0}^{\ln(4)} e^{x}\,dx$$.
Filling a Tank: Antiderivative with Initial Value
Water is entering a tank at a rate given by $$r(t)= \frac{2}{t+1}$$ liters per minute. The initial
Fundamental Theorem and Total Accumulated Growth
A bacteria culture grows according to the logistic model $$\frac{dN}{dt}=N\left(1-\frac{N}{10000}\r
Heat Energy Accumulation
The rate of heat transfer into a container is given by $$H(t)= 5\sin(t)$$ kJ/min for $$t \in [0,\pi]
Integration by U-Substitution and Evaluation of a Definite Integral
Evaluate the definite integral $$\int_{0}^{1} \frac{2*t}{(t^2+1)^2}\, dt$$ by applying U-substitut
Non-Uniform Subinterval Riemann Sum
A function $$f(t)$$ is measured at non-uniform time intervals as recorded in the table below: | t (
Population Model Inversion and Accumulation
Consider the logistic-type function $$f(t)= \frac{8}{1+e^{-t}}$$, representing a population model, d
Power Series Analysis and Applications
Consider the function with the power series representation $$f(x)=\sum_{n=0}^\infty \frac{(-1)^n x^{
Riemann Sum from a Table: Plant Growth Data
A function $$f(t)$$ describes the height (in cm) of a plant over time (in days). The measurements ar
Riemann Sums and Inverse Analysis from Tabular Data
Let $$f(x)= 2*x + 1$$ be defined on the interval $$[0,5]$$. Answer the following questions about $$f
Rocket Height Determination via U-Substitution
A rocket’s velocity is modeled by the function $$v(t)=t * e^(t^(2))$$ (in m/s) for $$t \ge 0$$. With
Scooter Motion with Variable Acceleration
A scooter's acceleration is given by $$a(t)= 2*t - 1$$ (m/s²) for $$t \in [0,5]$$, with an initial v
Series Representation and Term Operations
Consider the power series for $$\arctan(x)$$ given by $$\sum_{n=0}^\infty (-1)^n \frac{x^{2n+1}}{2n+
Tank Filling Problem
Water flows into a tank at a rate given by $$R(t)=8e^{-0.5*t}+2$$ (in liters per minute) for $$t\geq
Trapezoidal and Riemann Sums from Tabular Data
A scientist collects data on the concentration of a chemical over time as given in the table below.
Trapezoidal Approximation of a Definite Integral from Tabular Data
The table below shows the height H(t) (in meters) of a liquid in a tank at specific times. Use a tra
Volume by Cross-Section: Squares on a Parabolic Base
A solid has a base in the xy-plane bounded by the curves $$y=x^2$$ and $$y=4$$. Cross-sections perpe
Volume of a Solid with Known Cross-sectional Area
A solid extends from $$x=0$$ to $$x=5$$, and its cross-sectional area perpendicular to the x-axis is
Water Tank Inflow and Outflow
A water tank begins operation at t = 0 with an initial volume of 0 liters. Water flows in through an
Work Done by a Variable Force
A variable force given by $$F(x)=4*x^2$$ (in Newtons) is applied along a straight line over the disp
Analysis of a Piecewise Function with Potential Discontinuities
Consider the piecewise defined function $$ f(x)=\begin{cases} \frac{x^2-4}{x-2} & \text{if } x < 2,
Capacitor Discharge in an RC Circuit
In an RC circuit, the voltage $$V(t)$$ across a discharging capacitor obeys the differential equatio
Complex Related Rates Problem Involving a Moving Ladder
A 10-meter ladder leans against a vertical wall. The bottom of the ladder slides away from the wall
Cooling with Time-Varying Ambient Temperature
An object cools according to the modified Newton's Law of Cooling given by $$\frac{dT}{dt}= -k*(T-T_
Differential Equations in Economic Modeling
An economist models the rate of change of a commodity price $$P(t)$$ with the differential equation
Direction Fields and Phase Line Analysis
Consider the autonomous differential equation $$\frac{dy}{dt}=(y-2)(3-y)$$. Answer the following par
Disease Spread Model
In a simplified epidemiological model, the number of infected individuals \(I(t)\) evolves according
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
Epidemic Spread Modeling
In a simplified epidemic model, the number of infected individuals $$I(t)$$ is modeled by the logist
Euler's Method Approximation
Consider the initial value problem $$\frac{dy}{dt}=t\sqrt{y}$$ with $$y(0)=1$$. Use Euler's method w
FRQ 5: Mixing Problem in a Tank
A tank initially contains 100 liters of water with 10 kg of dissolved salt. Brine with a salt concen
FRQ 8: RC Circuit Analysis
In an RC circuit, the voltage across the capacitor, $$V(t)$$, satisfies the differential equation $$
FRQ 18: Enzyme Reaction Rates
A chemical concentration $$C(t)$$ in a reaction decreases according to the differential equation $$\
Growth and Decay in a Bioreactor
In a bioreactor, the concentration of a chemical P (in mg/L) evolves according to the differential e
Homogeneous Differential Equation
Solve the homogeneous differential equation $$\frac{dy}{dx}= \frac{x^2+y^2}{x*y}$$ using the substit
Implicit Differentiation and Homogeneous Equation
Consider the differential equation $$\frac{dy}{dx}= \frac{x+y}{x-y}$$. Answer the following:
Infectious Disease Spread Model
In a closed population of N individuals, the number of infected individuals $$I(t)$$ is modeled by t
Interpreting Slope Fields for a Differential Equation
Consider the differential equation $$\frac{dy}{dx}= x-y$$. A slope field for this differential equat
Investment Growth with Nonlinear Dynamics
The rate of change of an investment amount $$I$$ is modeled by the nonlinear differential equation $
Logistic Equation with Harvesting
A fish population in a lake follows a logistic growth model with the addition of a constant harvesti
Logistic Population Model
A fish population is modeled by the logistic differential equation $$\frac{dP}{dt}= r*P\left(1-\frac
Medicine Infusion and Elimination Model
A patient receives an intravenous infusion of a drug such that the infusion rate is $$R(t)=e^{0.2*t}
Mixing Problem in a Tank
A tank initially contains 100 L of water with 5 kg of dissolved salt. Brine containing 0.1 kg of sal
Modeling Cooling and Heating: Temperature Differential Equation
Suppose the temperature of an object changes according to the differential equation $$\frac{dT}{dt}
Modeling Disease Spread with Differential Equations
In a simple model for disease spread, the number of infected individuals, $$I(t)$$, evolves accordin
Modeling Free Fall with Air Resistance
An object falls under gravity while experiencing air resistance proportional to its velocity. The mo
Newton's Law of Cooling
A hot liquid cools in a room maintained at a constant temperature $$T_{room}$$. The temperature $$T(
Population Dynamics with Harvesting
Consider a population model that includes constant harvesting, given by the differential equation $$
Population Growth with Logistic Differential Equation
A population $$P(t)$$ is modeled by the logistic differential equation $$\frac{dP}{dt} = r\,P\left(1
Projectile Motion with Air Resistance
A projectile is fired vertically upward with an initial velocity of $$50\,m/s$$. The projectile expe
RC Circuit: Voltage Decay
In an RC circuit, the voltage across a capacitor satisfies $$\frac{dV}{dt} = -\frac{1}{R*C} * V$$. G
Reservoir Contaminant Dilution
A reservoir has a constant volume of 10,000 L and contains a pollutant with amount $$Q(t)$$ (in kg)
Saltwater Mixing Problem
A tank initially contains 1000 L of a salt solution with a concentration of 0.2 kg/L (thus 200 kg of
Separable Differential Equation and Maclaurin Series Approximation
Consider the differential equation $$\frac{dy}{dx} = e^{x} * \sin(y)$$ with the initial condition $$
Separable Differential Equation and Slope Field Analysis
Consider the differential equation $$\frac{dy}{dx} = \frac{4*x}{y}$$ with the initial condition $$y(
Separation of Variables with Trigonometric Functions
Solve the differential equation $$\frac{dy}{dx} = \frac{\sin(x)}{1+y^2}$$ by using separation of var
Temperature Change with Variable Ambient Temperature
A heated object is cooling in an environment where the ambient temperature changes over time. For $$
Arc Length of a Logarithmic Curve
Determine the arc length of the curve $$f(x)= \ln(x)$$ on the interval $$[1,e]$$.
Area Between Curves in Window Design
An architect is designing a decorative window whose outline is bounded by the curves $$y=5*x-x^2$$ a
Area Between Curves: Parabolic and Linear Functions
Consider the functions $$f(x)=5*x-x^2$$ and $$g(x)=x$$. Determine the area enclosed between these cu
Area Calculation: Region Under a Parabolic Curve
Let $$f(x)=4-x^2$$. Consider the region bounded by the curve $$f(x)$$ and the x-axis.
Average and Instantaneous Acceleration
For a particle, the acceleration is given by $$a(t)=4*\sin(t)-t$$ (in m/s²) for $$t\in[0,\pi]$$. Giv
Average Chemical Concentration Analysis
In a chemical reaction, the concentration of a reactant (in M) is recorded over time as given in the
Average Daily Temperature
The temperature during a day is modeled by $$T(t)=10+5*\sin((\pi/12)*t)$$ (in °C), where $$t$$ is th
Average Temperature of a Day
In a certain city, the temperature during the day is modeled by a continuous function $$T(t)$$ for $
Average Value of a Temperature Function
A region’s temperature throughout a day is modeled by the function $$T(t)=10+5*\sin(\frac{\pi}{12}*t
Average Value of a Trigonometric Function
A function representing sound intensity is given by $$I(t)= 4*\cos(2*t) + 10$$ over the time interva
Center of Mass of a Non-uniform Rod
A thin rod of length 10 m has a linear density given by $$\lambda(x)= 3 + 0.5*x$$ (in kg/m) for $$0
Center of Mass of a Rod with Variable Density
A rod extending along the x-axis from $$x=0$$ to $$x=10$$ meters has a density given by $$\rho(x)=2+
Cost Analysis: Area Between Production Cost Curves
Suppose two cost functions for producing goods are given by $$f(x)=20+2*x$$ and $$g(x)=5*x-\frac{1}{
Distance Traveled from a Velocity Function
A car has a velocity function given by $$v(t)=t^2-4*t+3$$ (in m/s) for $$t$$ in seconds from 0 to 5.
Economic Analysis: Consumer and Producer Surplus
In a market analysis, the demand and supply for a product are modeled by the equations: Demand: $$D(
Electrical Charge Distribution
A wire of length 3 meters carries a charge distribution given by $$\rho(x)=\frac{5}{1+x^2}$$ (in cou
Kinematics: Motion with Variable Acceleration
A particle moves along a straight line with acceleration $$a(t)=4-2*t$$ (in m/s²). The particle has
Optimization of Material Usage in a Container
A container's volume is given by $$V(h)=\int_0^h \pi*(3-0.5*\ln(1+x))^2dx$$, where $$h$$ is the heig
Particle Motion: Position, Velocity, and Acceleration
A particle moves along a straight line with acceleration given by $$a(t)=3*t-4$$ (in m/s²). At time
Position and Velocity from Tabulated Data
A particle’s velocity (in m/s) is measured at discrete time intervals as shown in the table. Use the
Projectile Motion under Gravity
An object is projected vertically upward with an initial velocity of $$20$$ m/s and from an initial
Rainfall Accumulation Analysis
A local weather station records the rainfall intensity (in mm/h) over a 6-hour period. Use integrati
Salt Concentration in a Mixing Tank
A tank initially contains 50 L of water with 5 g of salt. A salt solution with a concentration of 0.
Surface Area of a Rotated Curve
Consider the curve $$y=x^3$$ on the interval $$[0,2]$$. This curve is rotated about the x-axis, form
Surface Area of a Rotated Parabolic Curve
The curve $$y = x^2$$ is rotated about the x-axis for $$x$$ in the interval $$[0,3]$$ to form a surf
Volume of a Solid by the Disc Method
Consider the region bounded by the curve $$y=\sqrt{x}$$ and the x-axis for $$x\in[0,4]$$. This regio
Volume of a Solid with Equilateral Triangle Cross Sections
Consider the region bounded by $$y= \sqrt{x}$$ and $$y=0$$ for $$x \in [0,1]$$. A solid is formed by
Volume of a Solid with Square Cross Sections
The base of a solid is the region in the plane bounded by $$y=x$$ and $$y=x^2$$ (with $$x$$ between
Volume of a Solid with Square Cross Sections
Consider the region bounded by the curve $$f(x)= 4 - x^2$$ and the x-axis for $$x \in [-2,2]$$. A so
Volume of a Wavy Dome
An auditorium roof has a varying cross-sectional area given by $$A(x)=\pi*(1 + 0.1*\sin(x))^2$$ (in
Volume of an Arch Bridge Support
The arch of a bridge is modeled by $$y=12-\frac{x^2}{4}$$ for $$x\in[-6,6]$$. Cross-sections perpend
Water Tank Dynamics: Inflow and Outflow
A water tank receives water through an inflow at a rate given by $$I(t)=10+2*t$$ (liters per minute)
Arc Length of a Decaying Spiral
Consider the parametric equations $$x(t)= e^{-t}\cos(t)$$ and $$y(t)= e^{-t}\sin(t)$$ for $$t \ge 0$
Circular Motion: Speed and Acceleration Components
A car travels around a circle of radius 5, described by the parametric equations $$x(t)=5\cos(t)$$ a
Converting Polar to Cartesian and Computing Slope
The polar curve is given by the equation $$r=4\cos(\theta)$$. Answer the following:
Designing a Roller Coaster: Parametric Equations
The path of a roller coaster is modeled by the equations $$x(t)=t-\sin(t)$$ and $$y(t)=1-\cos(t)$$ f
Dynamics in Polar Coordinates
A particle moves such that its polar coordinates are given by $$ r(\theta)=1+\theta $$, where $$ \th
Implicit Differentiation and Curves in the Plane
The curve defined by $$x^2y + xy^2 = 12$$ describes a relation between $$x$$ and $$y$$.
Inner Loop of a Limaçon in Polar Coordinates
The polar curve given by \(r=1+2\cos(\theta)\) forms a limaçon with an inner loop. Answer the follow
Intersection of Polar Curves
Consider the polar curves given by $$r=2\sin(\theta)$$ and $$r=1+\cos(\theta)$$. Answer the followin
Modeling Periodic Motion with a Vector Function
A particle moves in the plane according to the vector function $$\mathbf{r}(t)=\langle \cos(2*t),\;
Parametric Motion and Change of Direction
A particle moves along a path defined by the parametric equations $$x(t)=t^3-3t$$ and $$y(t)=2t^2$$
Parametric Representation of an Ellipse
An ellipse is represented by the parametric equations $$x(t)=4\cos(t)$$ and $$y(t)=3\sin(t)$$ for $$
Particle Trajectory in Parametric Motion
A particle moves along a curve with parametric equations $$x(t)= t^2 - 4*t$$ and $$y(t)= t^3 - 3*t$$
Periodic Motion: A Vector-Valued Function
A point moves on a circle with position given by $$\vec{r}(t)= \langle \cos(2t), \sin(2t) \rangle$$
Polar Coordinate Area Calculation
Consider the polar curve $$r=4*\sin(θ)$$ for $$0 \le θ \le \pi$$. This equation represents a circle.
Polar Differentiation and Tangent Lines
Consider the polar curve $$r(\theta)= 1+\cos(\theta)$$.
Polar Equations and Slope Analysis
Given the polar curve $$r = 4\sin(\theta)$$, analyze its Cartesian form and tangent properties.
Polar to Parametric Conversion and Arc Length
A curve is defined in polar coordinates by $$r= 1+\sin(\theta)$$. Convert and analyze the curve.
Projectile Motion Modeled by Vector-Valued Functions
A projectile is launched with an initial velocity vector $$\vec{v}_0=\langle 10, 20 \rangle$$ (in m/
Projectile Motion using Parametric Equations
A projectile is launched with an initial speed of $$v_0 = 20\,\text{m/s}$$ at an angle of $$30^\circ
Projectile Motion via Vector-Valued Functions
A projectile is launched from the origin with an initial velocity given by \(\mathbf{v}(0)=\langle 5
Reparameterization between Parametric and Polar Forms
A curve is described by the parametric equations $$x(t)=a*t$$ and $$y(t)=b*t^2$$, where $$a$$ and $$
Synthesis of Parametric, Polar, and Vector Concepts
A drone's flight path is given in polar coordinates by $$r(\theta)= 5+ 2\sin(\theta)$$. It is parame
Tangent Line to a 3D Vector-Valued Curve
Let $$\textbf{r}(t)= \langle t^2, \sin(t), \ln(t+1) \rangle$$ for $$t \in [0,\pi]$$. Answer the foll
Vector-Valued Functions: Motion in the Plane
The position of a particle in space is given by $$\vec{r}(t)=\langle e^t, \ln(1+t), t^2 \rangle$$ fo
Work Done by a Force along a Vector Path
A force field is given by $$\mathbf{F}(t)=\langle2*t,\;3\sin(t)\rangle$$ and an object moves along a
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