Note that in this post we will be looking at differentiating cos(3x) which is not the same as differentiating cos3x). Here is our post dealing with how to differentiate cos3(x).
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate cos(x) (the answer is -sin(x))
We know how to differentiate 3x (the answer is 3)
This means the chain rule will allow us to differentiate the expression cos(3x).
Using the chain rule to find the derivative of cos(3x)
To perform the differentiation cos(3x), the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression is actually in terms of (in this case the derivative of 3x).
Let’s call the function in the argument of cos, g(x), which means the function is in the form of cos(x), except it does not have x as the angle, instead it has another function of x (3x) as the angle
If:
g(x) = 3x
It follows that:
cos(3x) = cos(g(x))
So if the function f(x) = cos(x) and the function g(x) = 3x, then the function cos(3x) can be written as a composite function.
f(x) = cos(x)
f(g(x)) = cos(g(x)) (but g(x) = 3x))
f(g(x)) = cos(3x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = cos(3x)
We can find the derivative of cos(3x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x)
If F(x) = f(g(x))
Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the cos function.
The derivative of cos(x) with respect to x is -sin(x) The derivative of cos(z) with respect to z is -sin(z)
In a similar way, the derivative of cos(3x) with respect to 3x is -sin(3x).
We will use this fact as part of the chain rule to find the derivative of cos(3x) with respect to x.
How to find the derivative of cos(3x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(3)
g(x) = 3x ⇒ g‘(x) = 3
= (-sin(3x)).(3)
f(g(x)) = cos(3x) ⇒f'(g(x)) = -sin(3x)
= -3sin(3x)
Using the chain rule, the derivative of cos(3x) is -3sin(3x)
Finally, just a note on syntax and notation: cos(3x) is sometimes written in the forms below (with the derivative as per the calculation above). Just be aware that not all of the forms below are mathematically correct.
cos3x
► Derivative of cos3x = -3sin(3x)
cos 3 x
► Derivative of cos 3 x = -3sin(3x)
cos 3x
► Derivative of cos 3x = -3sin(3x)
cos (3x)
► Derivative of cos (3x) = -3sin(3x)
The Second Derivative Of cos(3x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of cos(3x) = -3sin(3x). So to find the second derivative of cos(3x), we just need to differentiate -3sin(3x)
We can use the chain rule to find the derivative of -3sin(3x) and it gives us a result of -9cos(3x)
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate ex (the answer is ex)
We know how to differentiate -2x (the answer is -2)
Because e^-2x is a function which is a combination of ex and -2x, it means we can perform the differentiation of e to the -2x by making use of the chain rule.
Using the chain rule to find the derivative of e^-2x
Although the function e-2x contains no parenthesis, we can still view it as a composite function (a function of a function).
If we add parenthesis around the exponent, we get e(-2x).
Now the function is in the form of the standard exponential function ex, except it does not have x as an exponent, instead the exponent is another function of x (-2x).
Let’s call the function in the exponent g(x), which means:
g(x) = -2x
From this it follows that:
e-2x = eg(x)
Let’s set f(x) = ex.
Then, because g(x) = -2x, the function e-2x can be written as a composite function of f(x) and g(x).
f(x) = ex
f(g(x)) = eg(x) (but g(x) = -2x)
Therefore, f(g(x)) = e-2x
Let’s define this composite function as F(x):
F(x) = f(g(x)) = e-2x
We can now find the derivative of F(x) = e^-2x, F'(x), by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x) If F(x) = f(g(x)) Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule to find the derivative of e to the -2x.
How to find the derivative of e^-2x using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(-2)
g(x) = -2x ⇒ g'(x) = –2
= (e^-2x).(-2)
f(g(x)) = e^-2x ⇒f'(g(x)) = e^-2x
= -2e^(-2x)
Using the chain rule, the derivative of e^-2x is -2e^-2x
Finally, just a note on syntax and notation: the exponential function e^-2x is sometimes written in the forms shown below (the derivative of each is as per the calculations above). Just be aware that not all of the forms below are mathematically correct.
e-2x
► Derivative of e-2x = -2e-2x
e^(-2x)
► Derivative of e^(-2x) = -2e-2x
e -2x
► Derivative of e -2x = -2e-2x
e -2 x
► Derivative of e -2 x = -2e-2x
e to the -2x
► Derivative of e to the -2x = -2e-2x
Top Tip
It’s possible to generalize the derivative of expressions in the form e^ax (where a is a constant value):
The derivative of eax = aeax
(Add the constant a to the front of the expression and keep the exponential part the same)
The Second Derivative of e^-2x
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of e^-2x = -2e^(-2x). So to find the second derivative of e^-2x, we just need to differentiate -2e-2x
We can use the chain rule to calculate the derivative of -2e-2x and get an answer of 4e-2x.
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate ex (the answer is ex)
We know how to differentiate -3x (the answer is -3)
Because e^-3x is a function which is a combination of ex and -3x, it means we can perform the differentiation of e to the -3x by making use of the chain rule.
Using the chain rule to find the derivative of e^-3x
Although the function e-3x contains no parenthesis, we can still view it as a composite function (a function of a function).
If we add parenthesis around the exponent, we get e(-3x).
Now the function is in the form of the standard exponential function ex, except it does not have x as an exponent, instead the exponent is another function of x (-3x).
Let’s call the function in the exponent g(x), which means:
g(x) = -3x
From this it follows that:
e-3x = eg(x)
Let’s set f(x) = ex.
Then, because g(x) = -3x, the function e-3x can be written as a composite function of f(x) and g(x).
f(x) = ex
f(g(x)) = eg(x) (but g(x) = -3x)
Therefore, f(g(x)) = e-3x
Let’s define this composite function as F(x):
F(x) = f(g(x)) = e-3x
We can now find the derivative of F(x) = e^-3x, F'(x), by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x) If F(x) = f(g(x)) Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule to find the derivative of e to the -3x.
How to find the derivative of e^-3x using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(-3)
g(x) = -3x ⇒ g'(x) = -3
= (e^-3x)(-3)
f(g(x)) = e^-3x ⇒f'(g(x)) = e^-3x
= -3e^(-3x)
Using the chain rule, the derivative of e^-3x is -3e^-3x
Finally, just a note on syntax and notation: the exponential function e^-3x is sometimes written in the forms shown below (the derivative of each is as per the calculations above). Just be aware that not all of the forms below are mathematically correct.
e-3x
► Derivative of e-3x = -3e-3x
e^(-3x)
► Derivative of e^(-3x) = -3e-3x
e -3x
► Derivative of e -3x = -3e-3x
e -3 x
► Derivative of e -3 x = -3e-3x
e to the -3x
► Derivative of e to the -3x = -3e-3x
Top Tip
It’s possible to generalize the derivative of expressions in the form e^ax (where a is a constant value):
The derivative of eax = aeax
(Add the constant a to the front of the expression and keep the exponential part the same)
The Second Derivative of e^-3x
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of e^-3x = -3e^(-3x). So to find the second derivative of e^-3x, we just need to differentiate -3e-3x
We can use the chain rule to calculate the derivative of -3e-3x and get an answer of 9e-3x.
Note that in this post we will be looking at differentiating sin(3x) which is not the same as differentiating sin3(x). Here is our post dealing with how to differentiate sin3(x).
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate sin(x) (the answer is cos(x))
We know how to differentiate 3x (the answer is 3)
This means the chain rule will allow us to differentiate the expression sin(3x).
Using the chain rule to find the derivative of sin(3x)
To perform the differentiation sin(3x), the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression is actually in terms of (in this case the derivative of 3x).
Let’s call the function in the argument of sin, g(x), which means the function is in the form of sin(x), except it does not have x as the angle, instead it has another function of x (3x) as the angle.
If:
g(x) = 3x
It follows that:
sin(3x) = sin(g(x))
So if the function f(x) = sin(x) and the function g(x) = 3x, then the function sin(3x) can be written as a composite function.
f(x) = sin(x)
f(g(x)) = sin(g(x)) (but g(x) = 3x))
f(g(x)) = sin(3x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = sin(3x)
We can find the derivative of sin(3x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x)
If F(x) = f(g(x))
Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the sin function.
The derivative of sin(x) with respect to x is cos(x) The derivative of sin(z) with respect to z is cos(z)
In a similar way, the derivative of sin(3x) with respect to 3x is cos(3x).
We will use this fact as part of the chain rule to find the derivative of sin(3x) with respect to x.
How to find the derivative of sin(3x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(3)
g(x) = 3x ⇒ g'(x) = 3
= (cos(3x)).(3)
f(g(x)) = sin(3x) ⇒f'(g(x)) = cos(3x)
= 3cos(3x)
Using the chain rule, the derivative of sin(3x) is 3cos(3x)
Finally, just a note on syntax and notation: sin(3x) is sometimes written in the forms below (with the derivative as per the calculation above). Just be aware that not all of the forms below are mathematically correct.
sin3x
► Derivative of sin3x = 3cos(3x)
sin3x
► Derivative of sin3x = 3cos(3x)
sin 3x
► Derivative of sin 3x = 3cos(3x)
sin (3x)
► Derivative of sin (3x) = 3cos(3x)
The Second Derivative Of sin(3x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of sin(3x) = 3cos(3x). So to find the second derivative of sin(3x), we just need to differentiate 3cos(3x)
We can use the chain rule to find the derivative of 3cos(3x) and it gives us a result of -9sin(3x)
There are two methods that can be used for calculating the derivative of ln(8x).
The first method is by using the chain rule for derivatives.
The second method is by using the properties of logs to write ln(8x) into a form which differentiable without needing to use the chain rule.
Finding the derivative of ln(8x) using the chain rule
The chain rule is useful for finding the derivative of an expression which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate 8x (the answer is 8)
We know how to differentiate ln(x) (the answer is 1/x)
This means the chain rule will allow us to perform the differentiation of the function ln(8x).
To perform the differentiation, the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression was actually in terms of (in this case the derivative of 8x).
Using the chain rule to find the derivative of ln(8x)
ln(8x) is in the form of the standard natural log function ln(x), except it does not have x as an argument, instead it has another function of x (8x).
Let’s call the function in the argument g(x), which means:
g(x) = 8x
From this it follows that:
ln(8x) = ln(g(x))
So if the function f(x) = ln(x) and the function g(x) = 8x, then the function ln(8x) can be written as a composite function.
f(x) = ln(x)
f(g(x)) = ln(g(x)) (but g(x) = 8x)
f(g(x)) = ln(8x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = ln(8x)
We can find the derivative of ln(8x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x) If F(x) = f(g(x)) Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule.
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the natural logarithm.
The derivative of ln(x) with respect to x is (1/x) The derivative of ln(s) with respect to s is (1/s)
In a similar way, the derivative of ln(8x) with respect to 8x is (1/8x). We will use this fact as part of the chain rule to find the derivative of ln(8x) with respect to x.
How to find the derivative of ln(8x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x)).(8)
g(x) = 8x ⇒ g'(x) = 8
= (1/8x).8
f(g(x)) = ln(8x) ⇒ f'(g(x)) = 1/8x (The derivative of ln(8x) with respect to 8x is (1/8x))
= 1/x
Using the chain rule, we find that the derivative of ln(8x) is 1/x
Finally, just a note on syntax and notation: ln(8x) is sometimes written in the forms below (with the derivative as per the calculations above). Just be aware that not all of the forms below are mathematically correct.
ln8x
► Derivative of ln8x =1/x
ln 8x
► Derivative of ln 8x = 1/x
ln 8 x
► Derivative of ln 8 x = 1/x
Top Tip
It’s possible to generalize the derivative of expressions in the form ln(ax) (where a is a constant value):
The derivative of ln(ax) = 1/x
(Regardless of the value of the constant, the derivative of ln(ax) is always 1/x)
Finding the derivative of ln(8x) using log properties
Since ln is the natural logarithm, the usual properties of logs apply.
The product property of logs states that ln(xy) = ln(x) + ln(y). In other words taking the log of a product is equal to the summing the logs of each term of the product.
Since 8x is the product of 8 and x, we can use the product properties of logs to rewrite ln(8x):
f(x) = ln(8x) = ln(8) + ln(x)
How to find the derivative of ln(8x) using the product property of logs
f(x)
= ln(8) + ln(x)
f'(x)
= 0 + ln(x)
ln8 is a constant, the derivative of a constant is 0
= 0 + 1/x
The derivative of ln(x) is 1/x
= 1/x
The Second Derivative of ln(8x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of ln(8x) = 1/x. So to find the second derivative of ln(8x), we just need to differentiate 1/x
If we differentiate 1/x we get an answer of (-1/x2).
Note that in this post we will be looking at differentiating tan(2x) which is not the same as differentiating tan2(x). Here is our post dealing with how to differentiate tan^2(x).
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate tan(x) (the answer is sec2(x))
We know how to differentiate 2x (the answer is 2)
This means the chain rule will allow us to differentiate the expression tan(2x).
Using the chain rule to find the derivative of tan(2x)
To perform the differentiation tan(2x), the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression is actually in terms of (in this case the derivative of 2x).
Let’s call the function in the argument of tan, g(x), which means the function is in the form of tan(x), except it does not have x as the angle, instead it has another function of x (2x) as the angle
If:
g(x) = 2x
It follows that:
tan(2x) = tan(g(x))
So if the function f(x) = tan(x) and the function g(x) = 2x, then the function tan(2x) can be written as a composite function.
f(x) = tan(x)
f(g(x)) = tan(g(x)) (but g(x) = 2x))
f(g(x)) = tan(2x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = tan(2x)
We can find the derivative of tan(2x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x)
If F(x) = f(g(x))
Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the tan function.
The derivative of tan(x) with respect to x is sec2(x) The derivative of tan(z) with respect to z is sec2(z)
In a similar way, the derivative of tan(2x) with respect to 2x is sec2(2x).
We will use this fact as part of the chain rule to find the derivative of tan(2x) with respect to x.
How to find the derivative of tan(2x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(2)
g(x) = 2x ⇒ g'(x) = 2
= (sec2(2x)).(2)
f(g(x)) = tan(2x) ⇒f'(g(x)) = sec2(2x)
= 2sec2(2x)
Using the chain rule, the derivative of tan(2x) is 2sec2(2x)
Finally, just a note on syntax and notation: tan(2x) is sometimes written in the forms below (with the derivative as per the calculation above). Just be aware that not all of the forms below are mathematically correct.
tan2x
► Derivative of tan2x = 2sec2(2x)
tan 2 x
► Derivative of tan 2 x = 2sec2(2x)
tan 2x
► Derivative of tan 2x = 2sec2(2x)
tan (2x)
► Derivative of tan (2x) = 2sec2(2x)
The Second Derivative Of tan(2x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of tan(2x) = 2sec2(2x). So to find the second derivative of tan(2x), we just need to differentiate 2sec2(2x).
We can use the chain rule to find the derivative of 2sec2(2x) (bearing in mind that the derivative of sec^2(x) is 2sec2(x)tan(x)) and it gives us a result of 8sec2(2x)tan(2x)
► The second derivative of tan(2x) is 8sec2(2x)tan(2x)
There are two methods that can be used for calculating the derivative of ln(7x).
The first method is by using the chain rule for derivatives.
The second method is by using the properties of logs to write ln(7x) into a form which differentiable without needing to use the chain rule.
Finding the derivative of ln(7x) using the chain rule
The chain rule is useful for finding the derivative of an expression which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate 7x (the answer is 7)
We know how to differentiate ln(x) (the answer is 1/x)
This means the chain rule will allow us to perform the differentiation of the function ln(7x).
To perform the differentiation, the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression was actually in terms of (in this case the derivative of 7x).
Using the chain rule to find the derivative of ln(7x)
ln(7x) is in the form of the standard natural log function ln(x), except it does not have x as an argument, instead it has another function of x (7x).
Let’s call the function in the argument g(x), which means:
g(x) = 7x
From this it follows that:
ln(7x) = ln(g(x))
So if the function f(x) = ln(x) and the function g(x) = 7x, then the function ln(7x) can be written as a composite function.
f(x) = ln(x)
f(g(x)) = ln(g(x)) (but g(x) = 7x)
f(g(x)) = ln(7x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = ln(7x)
We can find the derivative of ln(7x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x) If F(x) = f(g(x)) Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule.
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the natural logarithm.
The derivative of ln(x) with respect to x is (1/x) The derivative of ln(s) with respect to s is (1/s)
In a similar way, the derivative of ln(7x) with respect to 7x is (1/7x). We will use this fact as part of the chain rule to find the derivative of ln(7x) with respect to x.
How to find the derivative of ln(7x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x)).(7)
g(x) = 7x ⇒ g'(x) = 7
= (1/7x).7
f(g(x)) = ln(7x) ⇒ f'(g(x)) = 1/7x (The derivative of ln(7x) with respect to 7x is (1/7x))
= 1/x
Using the chain rule, we find that the derivative of ln(7x) is 1/x
Finally, just a note on syntax and notation: ln(7x) is sometimes written in the forms below (with the derivative as per the calculations above). Just be aware that not all of the forms below are mathematically correct.
ln7x
► Derivative of ln7x =1/x
ln 7x
► Derivative of ln 7x = 1/x
ln 7 x
► Derivative of ln 7 x = 1/x
Top Tip
It’s possible to generalize the derivative of expressions in the form ln(ax) (where a is a constant value):
The derivative of ln(ax) = 1/x
(Regardless of the value of the constant, the derivative of ln(ax) is always 1/x)
Finding the derivative of ln(7x) using log properties
Since ln is the natural logarithm, the usual properties of logs apply.
The product property of logs states that ln(xy) = ln(x) + ln(y). In other words taking the log of a product is equal to the summing the logs of each term of the product.
Since 7x is the product of 7 and x, we can use the product properties of logs to rewrite ln(7x):
f(x) = ln(7x) = ln(7) + ln(x)
How to find the derivative of ln(7x) using the product property of logs
f(x)
= ln(7) + ln(x)
f'(x)
= 0 + ln(x)
ln7 is a constant, the derivative of a constant is 0
= 0 + 1/x
The derivative of ln(x) is 1/x
= 1/x
The Second Derivative of ln(7x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of ln(7x) = 1/x. So to find the second derivative of ln(7x), we just need to differentiate 1/x
If we differentiate 1/x we get an answer of (-1/x2).
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate ex (the answer is ex)
We know how to differentiate 9x (the answer is 9)
Because e^9x is a function which is a combination of ex and 9x, it means we can perform the differentiation of e to the 9x by making use of the chain rule.
Using the chain rule to find the derivative of e^9x
Although the function e9x contains no parenthesis, we can still view it as a composite function (a function of a function).
If we add parenthesis around the exponent, we get e(9x).
Now the function is in the form of the standard exponential function ex, except it does not have x as an exponent, instead the exponent is another function of x (9x).
Let’s call the function in the exponent g(x), which means:
g(x) = 9x
From this it follows that:
e9x = eg(x)
Let’s set f(x) = ex.
Then, because g(x) = 9x, the function e9x can be written as a composite function of f(x) and g(x).
f(x) = ex
f(g(x)) = eg(x) (but g(x) = 9x)
Therefore, f(g(x)) = e9x
Let’s define this composite function as F(x):
F(x) = f(g(x)) = e9x
We can now find the derivative of F(x) = e^9x, F'(x), by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x) If F(x) = f(g(x)) Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule to find the derivative of e to the 9x.
How to find the derivative of e^9x using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(9)
g(x) = 9x ⇒ g'(x) = 9
= (e^9x).9
f(g(x)) = e^9x ⇒f'(g(x)) = e^9x
= 9e^(9x)
Using the chain rule, the derivative of e^9x is 9e^9x
Finally, just a note on syntax and notation: the exponential function e^9x is sometimes written in the forms shown below (the derivative of each is as per the calculations above). Just be aware that not all of the forms below are mathematically correct.
e9x
► Derivative of e9x = 9e9x
e^(9x)
► Derivative of e^(9x) = 9e9x
e 9x
► Derivative of e 9x = 9e9x
e 9 x
► Derivative of e 9 x = 9e9x
e to the 9x
► Derivative of e to the 9x = 9e9x
Top Tip
It’s possible to generalize the derivative of expressions in the form e^ax (where a is a constant value):
The derivative of eax = aeax
(Add the constant a to the front of the expression and keep the exponential part the same)
The Second Derivative of e^9x
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of e^9x = 9e^(9x). So to find the second derivative of e^9x, we just need to differentiate 9e9x
We can use the chain rule to calculate the derivative of 9e9x and get an answer of 81e9x.
Note that in this post we will be looking at differentiating cos(2x) which is not the same as differentiating cos2(x). Here is our post dealing with how to differentiate cos^2(x).
The chain rule is useful for finding the derivative of a function which could have been differentiated had it been in x, but it is in the form of another expression which could also be differentiated if it stood on its own.
In this case:
We know how to differentiate cos(x) (the answer is -sin(x))
We know how to differentiate 2x (the answer is 2)
This means the chain rule will allow us to differentiate the expression cos(2x).
Using the chain rule to find the derivative of cos(2x)
To perform the differentiation cos(2x), the chain rule says we must differentiate the expression as if it were just in terms of x as long as we then multiply that result by the derivative of what the expression is actually in terms of (in this case the derivative of 2x).
Let’s call the function in the argument of cos, g(x), which means the function is in the form of cos(x), except it does not have x as the angle, instead it has another function of x (2x) as the angle
If:
g(x) = 2x
It follows that:
cos(2x) = cos(g(x))
So if the function f(x) = cos(x) and the function g(x) = 2x, then the function cos(2x) can be written as a composite function.
f(x) = cos(x)
f(g(x)) = cos(g(x)) (but g(x) = 2x))
f(g(x)) = cos(2x)
Let’s define this composite function as F(x):
F(x) = f(g(x)) = cos(2x)
We can find the derivative of cos(2x) (F'(x)) by making use of the chain rule.
The Chain Rule: For two differentiable functions f(x) and g(x)
If F(x) = f(g(x))
Then the derivative of F(x) is F'(x) = f’(g(x)).g’(x)
Now we can just plug f(x) and g(x) into the chain rule. But before we do that, just a quick recap on the derivative of the cos function.
The derivative of cos(x) with respect to x is -sin(x) The derivative of cos(z) with respect to z is -sin(z)
In a similar way, the derivative of cos(2x) with respect to 2x is -sin(2x).
We will use this fact as part of the chain rule to find the derivative of cos(2x) with respect to x.
How to find the derivative of cos(2x) using the Chain Rule:
F'(x)
= f'(g(x)).g'(x)
Chain Rule Definition
= f'(g(x))(2)
g(x) = 2x ⇒ g'(x) = 2
= (-sin(2x)).(2)
f(g(x)) = cos(2x) ⇒f'(g(x)) = -sin(2x)
= -2sin(2x)
Using the chain rule, the derivative of cos(2x) is -2sin(2x)
Finally, just a note on syntax and notation: cos(2x) is sometimes written in the forms below (with the derivative as per the calculation above). Just be aware that not all of the forms below are mathematically correct.
cos2x
► Derivative of cos2x = -2sin(2x)
cos 2 x
► Derivative of cos 2 x = -2sin(2x)
cos 2x
► Derivative of cos 2x = -2sin(2x)
cos (2x)
► Derivative of cos (2x) = -2sin(2x)
The Second Derivative Of cos(2x)
To calculate the second derivative of a function, you just differentiate the first derivative.
From above, we found that the first derivative of cos(2x) = -2sin(2x). So to find the second derivative of cos(2x), we just need to differentiate -2sin(2x)
We can use the chain rule to find the derivative of -2sin(2x) and it gives us a result of -4cos(2x)
In calculus, the quotient rule is used to find the derivative of a function which can be expressed as a ratio of two differentiable functions. In other words, the quotient rule allows us to differentiate functions which are in fraction form.
Say for example we had two functions:
f(x) = x2 and g(x) = x
Now say we wanted to find the derivative of
One approach to find the derivative would be to simplify the function and then differentiate it.
So the derivative of the fraction f(x)/g(x) is just 1.
Now, out of interest, let’s calculate f’(x)/g’(x) (by differentiating the numerator and then the denominator)
So we can see that (f(x)/g(x))’ = 1, and that is not equal to (f’(x)/g’(x)) = 2x
The derivative of a quotient is not equal to the quotient of the derivatives.
To differentiate a quotient, you cannot just take the derivative of the numerator and divide it by the derivative of the denominator. Instead, we need to use the quotient rule to find the derivative of a quotient (in a similar way that the product rule needs to be used to find the derivative of a product).
The Quotient Rule Formula For Differentiation
If two functions f(x) and g(x) are differentiable (i.e. the derivatives of f(x) and g(x) exist), then their quotient (f(x)/g(x)) is differentiable, and the derivative can be found as follows:
The formula for the quotient rule in words
The Quotient Rule states that the derivative of a quotient is equal to the denominator times the derivative of the numerator minus the numerator times the derivative of the denominator, all divided by the square of the denominator.
Two tricks to remember the quotient rule
Similar to the product rule, you need to find the derivative of f(x) and then multiply it with g(x) and then find the derivative of g(x) and multiply it by f(x). However, because the terms are subtracted, the order matters, and there is also a division which needs to be performed.
This makes the quotient rule a little more difficult to memorize compared to the product rule.
Here are two methods which may help you remember the quotient rule:
1. You always start with the bottom function (denominator) and end with the bottom function squared.
And if that doesn’t work…
2. Here is a jingle which you can use:
Lo d hi minus hi d low, all over the square of what’s below.
Here the lo, refers to the denominator, hi refers to the numerator and d refers to “the derivative of”. It’s really silly, but that’s why it works!
When to use the quotient rule
In calculus, the quotient rule can be applied when the function you want to differentiate consists of a quotient (or fraction), and the numerator and denominator of the quotient are both differentiable functions of their own.
For example the function f(x) = x/x2 can be differentiated using the quotient rule for derivatives because:
The numerator (x) is differentiable – its derivative is 1
The denominator (x2) is differentiable – it’s derivative is x
(Of course you could also first simplify the function to 1/x and then differentiate it and get the same result)
Examples Using The Quotient Rule
The best way to see how the quotient rule works is by looking at some examples.
Using the quotient rule
For the first example, let’s find the derivative of
Let’s call the numerator f(x), so f(x) = x2 + 1 Let’s call the denominator g(x), so g(x) = x3
This means that: f'(x) = 2x g'(x) = 3x2
We can now apply the quotient rule to find the derivative of f(x)/g(x). The formula for the quotient rule is
Now we can plug f(x), f'(x), g(x) and g'(x) into the formula
And then we just simplify using factorization and the rules of exponents to find the final answer
Using the quotient rule with trig functions
As another example, we can use the quotient rule to find the derivative of tan(x)
First recall that tan(x) can be expressed as sin(x) divided by cos(x)
Let’s call the numerator f(x), so f(x) = sin(x) Let’s call the denominator g(x), so g(x) = cos(x)
This means that: f'(x) = cos(x) g'(x) = -sin(x)
We can now apply the quotient rule to find the derivative of f(x)/g(x). The formula for the quotient rule is
Now we can plug f(x), f'(x), g(x) and g'(x) into the formula:
Then simplify remembering the trig identity sin2(x) + cos2(x) = 1 and recalling that 1/cos(x) is equal to sec(x).
Using the quotient rule, the derivative of tan(x) is equal to sec2(x)
Proof of the Quotient Rule
There are a number of ways to prove the quotient rule. Here we will look at proving the quotient rule using:
First principles – the derivative definition and properties of limits.
This can be rewritten by finding the lowest common denominator in the numerator (g(x+h).g(x)) and taking the 1/h out.
The next step is needed to make life easier a little later on. What we do is we add 0 to the numerator, which does not change the value at all. But instead of adding a straight 0, we add it in the form -f(x)g(x) + f(x)g(x)
Now we swap the two denominators around – we are allowed to do this since we are multiplying fractions.
Next we use one of the properties of limits which says that the limit of a product of two functions is equal to the product of their limits. We then also use the fact that the limit as h approaches zero of g(x+h) is simply g(x)
Now we split the large fraction up, and take out a common g(x) from the first part and a common -f(x) from the second part.
Another property of limits is that the limit of a sum is equal to the sum of the limits. So we can take the limit of each fraction separately.
And then we can take the limit of each part of the products
Now you may notice that two of the above limits look familiar – they are the exact definitions for f'(x) and g'(x).
Lastly, the limit as h approaches 0 of g(x) and f(x) remain g(x) and f(x) (since they are not dependent on h). And then all that is left to do is to rewrite everything in the simplest form. And there we have it – the formula for the quotient rule.
Proving the quotient rule using implicit differentiation and the product rule
Let y = f(x)/g(x), then we want to find y’.
First let’s rearrange the equation:
Now we can take the derivative on the left and right hand sides of the equation (by using the product rule on the right hand side)
Next, substitute y = f(x)/g(x) into the above equation
We ultimately want to find the derivative of y (y’) so now we solve for y’ and find the formula for the quotient rule.
Proving the quotient rule using the product and chain rules
To find (g(x)-1)’ we can apply the chain rule. The chain rule says we first take the derivative of g(x)-1 in terms of g(x) (= (-1)g(x)-2) and then multiply that by the derivative of g(x) in terms of x (= g'(x)).
Next we bring the negative exponents to the denominator and then simplify by finding the greatest common denominator. We are left with the formula for the quotient rule.
Proving the quotient rule using ln and the chain rule
Let y = f(x)/g(x)
To start, take the natural logarithm (ln) on both sides
Next apply the properties of logs to split the right hand side’s quotient to a difference of logs
Now take the derivative on both sides. Recall that the derivative of ln(x) with respect to x is 1/x. In a similar way, the derivative of ln(y) with respect to y is 1/y, the derivative of ln(f(x)) with respect to f(x) is 1/f(x) and the derivative of ln(g(x)) with respect to g(x) is 1/g(x).
To find the derivatives of each of the terms with respect to x, we can apply the chain rule by first differentiating with respect to the inner function of ln, and then multiplying that by the derivative of the inner function.
Lastly, isolate y’, substitute y = f(x)/g(x) in, and then simplify to solve for y’
The quotient rule in terms of u and v
With regards to notation, the quotient rule is sometimes easier to express if you use u and v to represent the numerator and denominator respectively. This can be more compact than using the function notation f(x) and g(x).
Using the variable u for the numerator, and v for the denominator, the quotient rule for finding the derivative of the function u/v can be expressed as:
