Grade 11
  1. Algebra  1.1. Sequences and Series  1.1.1. Arithmetic Sequence  1.1.2. Arithmetic Series  1.1.3. Geometric Sequence  1.1.4. Geometric Series  1.1.5. Convergence and Divergence  1.1.6. Sum to Infinity  1.1.7. Sigma Notation  1.2. Complex Numbers  1.2.1. Imaginary and Complex Numbers  1.2.2. Operations with Complex Numbers  1.2.3. Polar and Cartesian Forms  1.2.4. Complex Conjugates  1.2.5. Modulus and Argument  1.2.6. De Moivre's Theorem  1.2.7. Powers and Roots of Complex Numbers  1.3. Binomial Theorem  1.3.1. Expansion of Binomials  1.3.2. General Term  1.3.3. Binomial Coefficients  1.3.4. Applications of Binomial Theorem  1.3.5. Pascal's Triangle
  2. Functions and Graphs  2.1. Types of Functions  2.1.1. Polynomial Functions  2.1.2. Rational Functions  2.1.3. Exponential Functions  2.1.4. Logarithmic Functions  2.1.5. Trigonometric Functions  2.1.6. Piecewise Functions  2.2. Transformations of Functions  2.2.1. Translations  2.2.2. Reflections  2.2.3. Dilations and Stretches  2.2.4. Rotations  2.3. Inverse Functions  2.3.1. Finding Inverses  2.3.2. Graphs of Inverse Functions  2.3.3. Properties of Inverse Functions  2.3.4. Restrictions for Inverses
  3. Trigonometry  3.1. Trigonometric Ratios and Identities  3.1.1. Basic Trigonometric Ratios  3.1.2. Pythagorean Identities  3.1.3. Sum and Difference Formulas  3.1.4. Double Angle Formulas  3.1.5. Half Angle Formulas  3.1.6. Product-to-Sum and Sum-to-Product Formulas  3.2. Trigonometric Equations  3.2.1. Solving Trigonometric Equations  3.2.2. General Solutions in Trigonometric Equations  3.3. Graphs of Trigonometric Functions  3.3.1. Sine Graph  3.3.2. Cosine Graph  3.3.3. Tangent Graph  3.3.4. Amplitude and Period Adjustments  3.3.5. Phase Shifts in Graphs of Trigonometric Functions  3.4. Applications of Trigonometry  3.4.1. Laws of Sines and Cosines  3.4.2. Area of Triangles  3.4.3. Solving Triangles  3.4.4. Bearings and Navigation
  4. Calculus  4.1. Limits and Continuity  4.1.1. Concept of a Limit  4.1.2. One-Sided Limits  4.1.3. Limits at Infinity  4.1.4. Continuity of a Function  4.1.5. Types of Discontinuities  4.2. Differentiation  4.2.1. Definition of Derivative  4.2.2. Rules of Differentiation  4.2.3. Higher Order Derivatives  4.2.4. Chain Rule  4.2.5. Product Rule  4.2.6. Quotient Rule  4.3. Applications of Differentiation  4.3.1. Rate of Change  4.3.2. Tangents and Normals  4.3.3. Maxima and Minima  4.3.4. Increasing and Decreasing Functions  4.3.5. Optimization Problems  4.3.6. Curve Sketching  4.3.7. Related Rates  4.4. Integration  4.4.1. Antiderivatives  4.4.2. Indefinite Integrals  4.4.3. Definite Integrals  4.4.4. Fundamental Theorem of Calculus  4.4.5. Techniques of Integration  4.4.6. Area Under a Curve  4.5. Applications of Integration  4.5.1. Area Between Curves  4.5.2. Volumes of Solids of Revolution  4.5.3. Average Value of a Function
  5. Vectors and Matrices  5.1. Vectors  5.1.1. Representation of Vectors  5.1.2. Vector Operations  5.1.3. Dot Product  5.1.4. Cross Product  5.1.5. Applications in Geometry  5.1.6. Projection of Vectors  5.2. Matrices  5.2.1. Types of Matrices  5.2.2. Matrix Operations  5.2.3. Determinants  5.2.4. Inverse of a Matrix  5.2.5. Solving Systems of Linear Equations  5.2.6. Cramer's Rule
  6. Probability and Statistics  6.1. Probability  6.1.1. Basic Probability Concepts  6.1.2. Conditional Probability  6.1.3. Independent and Dependent Events  6.1.4. Bayes' Theorem  6.1.5. Combinatorial Probability  6.2. Random Variables  6.2.1. Discrete Random Variables  6.2.2. Continuous Random Variables  6.2.3. Probability Distributions  6.3. Probability Distributions  6.3.1. Binomial Distribution  6.3.2. Normal Distribution  6.3.3. Poisson Distribution  6.3.4. Uniform Distribution  6.4. Statistics  6.4.1. Measures of Central Tendency  6.4.2. Measures of Dispersion  6.4.3. Data Collection and Representation  6.4.4. Correlation and Regression  6.4.5. Sampling Techniques
  7. Coordinate Geometry  7.1. Straight Lines  7.1.1. Slope and Intercept Form  7.1.2. Distance Formula  7.1.3. Midpoint Formula  7.1.4. Angle Between Lines  7.1.5. Equation of Lines  7.2. Conic Sections  7.2.1. Circle  7.2.2. Parabola  7.2.3. Ellipse  7.2.4. Hyperbola  7.2.5. Properties of Conics  7.2.6. Parametric Equations of Conics  7.2.7. Polar Coordinates of Conics
  8. Mathematical Reasoning  8.1. Logic  8.1.1. Statements and Logical Connectives  8.1.2. Truth Tables  8.1.3. Logical Equivalence  8.1.4. Quantifiers  8.1.5. Proof Techniques  8.2. Proofs  8.2.1. Direct Proof  8.2.2. Indirect Proof  8.2.3. Proof by Contradiction  8.2.4. Proof by Mathematical Induction

Grade 11CalculusApplications of Differentiation


Increasing and Decreasing Functions


In calculus, one of the main things we study is how functions change as you move across the x-axis. Knowing whether a function is increasing or decreasing can help us understand the behavior of a function and make predictions about it. In this article, we will explore increasing and decreasing functions using simple language, examples, and diagrams.

Basic definitions

An increasing function is a function where, as you move from left to right along the x-axis, the y-values (or outputs) get larger. In simple terms, if you imagine moving from left to right along the graph, you will be moving upwards if the function is increasing.

A decreasing function is a function where the y-values get smaller as you move from left to right along the x-axis. In other words, you'll be moving downward as you move from left to right along the graph.

Mathematical definition

Let us consider a function f(x) on an interval I (say [a, b]). The function f(x) is:

  • It is strictly increasing if x_1 < x_2 for any x_1, x_2 in I, we have f(x_1) < f(x_2).
  • It is strictly decreasing if x_1 < x_2 for any x_1, x_2 in I, we have f(x_1) > f(x_2)

This means that for a strictly increasing function, as x gets larger, f(x) gets larger. Conversely, for a strictly decreasing function, as x gets larger, f(x) gets smaller.

The role of derivatives

The derivative is a powerful tool in calculus that determines whether a function is increasing or decreasing. The derivative of a function tells us the rate at which the value of the function is changing.

- If the derivative f'(x) > 0 on an interval, then the function is increasing on that interval.

- If the derivative f'(x) < 0 on an interval, then the function is decreasing on that interval.

- If f'(x) = 0, then the value of the function in that small interval may be constant, or it may be a turning point. More investigation is needed to determine this precisely.

Visualization with graphs

Let's look at this concept with a graph. Consider a simple quadratic function f(x) = x^2.

f'(x) = 2x

- For x > 0, f'(x) = 2x > 0, so the function is increasing in this region.

For - x < 0, f'(x) = 2x < 0, so the function is decreasing in this region.

The graph of f(x) = x^2:

Increasing Reduce

Example with cubic function

Let's look at another example, a cubic function: f(x) = x^3 - 3x^2 + 4.

f'(x) = 3x^2 - 6x

We set the derivative equal to zero to find the critical point.

0 = 3x^2 - 6x 0 = 3x(x - 2)

This gives us two solutions for x: x = 0 and x = 2 We will use these points to determine intervals where the function increases or decreases.

- The derivative is positive on the interval x < 0, thus the function is increasing.

- The derivative on the interval 0 < x < 2 is negative, which means the function is decreasing.

- The derivative on the interval x > 2 is again positive, so the function is increasing.

The graph of f(x) = x^3 - 3x^2 + 4:

Increasing Reduce

Real-world examples

Economics: Supply and demand

In economics, the concept of increasing and decreasing functions is often used in the context of supply and demand. Generally, as the price of a commodity increases, the supply of that commodity also increases (increasing function). Conversely, as the price increases, demand usually decreases (decreasing function). These relationships can be analyzed to find optimal pricing strategies using derivatives.

For example, consider the demand function D(p) = 500 - 20p, where p is the price of a product.

D'(p) = -20

Since D'(p) < 0, the demand function is decreasing; higher prices lead to lower demand.

Physics: Objects rising or falling

Consider a ball thrown upwards whose velocity function v(t) = 20 - 9.8t, where t is the time in seconds. Here, v is the velocity, which is a function of time.

v'(t) = -9.8

The derivative v'(t) < 0 shows that the velocity is decreasing with time, which means the ball is slowing down as it rises.

Conclusion

Understanding whether functions are increasing or decreasing is an important aspect of calculus, providing information about the behavior of a function. By examining the derivative of a function, we can predict where the function is going up or down and understand real-world phenomena such as economic trends or the movement of objects. With this knowledge, we can solve practical problems and make informed decisions based on the changing rates of a function.

In calculus, especially for students at this level, the emphasis is often on how functions change and how to apply this understanding to various fields such as physics, economics, and others. Mastering these concepts lays the groundwork for advanced study in mathematics and its applications.


Grade 11 → 4.3.4


U
username
0%
completed in Grade 11

← Prev (4.3.3)
Maxima and Minima
Next (4.3.5) →
Optimization Problems

Comments 



Increasing and Decreasing Functions

https://www.buddymath.com/g11/4.3.4?bmal=en