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Differentiation class11| DIFFERENTIATION | BEGINNER'S COURSE JEE 2025 / 2026
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- Опубліковано 6 лип 2024
- Differentiation class11| DIFFERENTIATION | BEGINNER'S COURSE JEE 2025 / 2026 #maths
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Infinite Series Differentiation (@Integralganit ) #class12mathematics
Infinite Series Differentiation:
Term-by-Term Differentiation of Infinite Series
Differentiation of Power Series
Infinite Series Differentiation Formula
Calculus:
Differentiating Infinite Series
Term-wise Differentiation of Infinite Series
Logarithmic Series Differentiation:
Differentiation of Logarithmic Functions
Logarithmic Differentiation Formula
Calculus:
Differentiating Logarithmic Series
Chain Rule for Logarithmic Differentiation
Differentiation of Logarithmic Functions using Chain Rule
Here are some key points about logarithmic differentiation and differentiating infinite series
Logarithmic Differentiation
Logarithmic differentiation is a technique used to differentiate large functions
It uses logarithms and the chain rule of differentiation
It is mainly used to differentiate functions of the form f(x)g(x)
It is useful for differentiating functions that are a product of multiple sub-functions
or if one function is divided by another function
or if a function is an exponent of another function
The formula for logarithmic differentiation is: d/dx (log f(x)) = f '(x)/f(x)
Differentiating Infinite Series
Infinite series can be differentiated term by term
The theorem states that if a sequence of functions {f_n} is differentiable on [a, b] and converges uniformly on [a, b] then the derivative of the sum of the series is equal to the sum of the derivatives of the individual terms
The theorem can be used to prove that a given infinite series can be differentiated term by term
However
the converse of the theorem is not always true
and it is not possible to differentiate an infinite series term by term in all cases
Differentiating an infinite series can be used to find the derivative of a function that is defined as an infinite sum
Here are the methods to differentiate logarithmic series and infinite series
Logarithmic Series:
Take the natural logarithm of both sides of the equation.
Use the chain rule to differentiate the logarithm.
Use the fact that d/dx (ln(u)) = u' / u.
Simplify the resulting expression.
Example: Differentiate ln(x^2 + 1)
ln(x^2 + 1)
(1 / (x^2 + 1)) * d/dx (x^2 + 1)
(1 / (x^2 + 1)) * 2x
2x / (x^2 + 1)
Infinite Series:
Differentiate each term of the series separately.
Use the power rule or product rule as needed.
Combine the results.
Example:
Differentiate Σ (n=1 to ∞) x^n
Differentiate each term: d/dx (x^n) = nx^(n-1)
Combine the results: Σ (n=1 to ∞) nx^(n-1)
Note: The infinite series must converge uniformly to justify term-by-term differentiation.
These methods will help you differentiate logarithmic series and infinite series
Differentiation has numerous applications in various fields, including:
Optimization
Find maximum and minimum values of functions, used in economics, physics, and engineering.
Physics
Describe motion, velocity, acceleration, and force.
Engineering
Design and optimize systems, like electronic circuits and mechanical systems.
Economics
Analyze economic systems, model growth and inflation, and optimize resource allocation.
Computer Science
Used in machine learning, game development, and algorithm optimization.
Medicine
Model population growth
drug delivery
and disease spread
Environmental Science
Study climate change
model population dynamics
and optimize resource management
Data Analysis
Find the rate of change of data, like stock prices or population growth
Machine Learning
Used in neural networks to optimize performance
Quality Control
Monitor and optimize production processes
Differentiation is a powerful tool for analyzing and understanding complex phenomena
helping us make informed decisions and drive innovation in various fields