Derivatives of hyperbolic functions
The derivatives of coshx and sinhx are derived from their definitions:
Given sinhx=2ex−e−x, differentiating with respect to x yields:
dxd(sinhx)=dxd(2ex−e−x)=2ex−(−e−x)=2ex+e−x=coshx
Therefore, dxd(sinhx)=coshx.
Similarly, given coshx=2ex+e−x, differentiating with respect to x yields:
dxd(coshx)=dxd(2ex+e−x)=2ex+(−e−x)=2ex−e−x=sinhx
Therefore, dxd(coshx)=sinhx.
Derivatives of other hyperbolic functions:
dxd(tanhx)=sech2x
dxd(cothx)=−cosech2x
dxd(sech x)=−sech xtanhx
dxd(cosech x)=−cosech xcothx
Example 1
Find the derivative of y=sinh(4x−8) with respect to x.
Solution:
dxdy=cosh(4x−8)⋅dxd(4x−8)=4cosh(4x−8)
Example 2
Find the derivative of y=ln(tanh2x) with respect to x.
Solution:
dxdy=tanh2x1⋅dxd(tanh2x)=tanh2x1⋅sech22x⋅2=tanh2x2sech22x=2cosh22x1⋅sinh2xcosh2x=sinh2xcosh2x2=2sinh2xcosh2x4=sinh4x4=4cosech 4x
Example 3
Find the minimum value of the function y=5coshx+3sinhx.
Solution:
dxdy=5sinhx+3coshx
For a minimum, dxdy=0, so 5sinhx+3coshx=0.
5(2ex−e−x)+3(2ex+e−x)=0
5ex−5e−x+3ex+3e−x=0
8ex−2e−x=0
8ex=2e−x
4ex=e−x
e2x=41
2x=ln(41)=−ln4
x=−21ln4=−ln2
Substituting x=−ln2 back into the original equation:
y=5cosh(−ln2)+3sinh(−ln2)=5(2e−ln2+eln2)+3(2e−ln2−eln2)=5(21/2+2)+3(21/2−2)=5(45)+3(4−3)=425−9=416=4
Therefore, the minimum value is 4.
Example 4
Find the derivative of y=1+tanh4xecosh6x−4sinh8x with respect to x.
Solution:
Using the quotient rule:
dxdy=(1+tanh4x)2(1+tanh4x)dxd(ecosh6x−4sinh8x)−(ecosh6x−4sinh8x)dxd(1+tanh4x)
=(1+tanh4x)2(1+tanh4x)(ecosh6x⋅6sinh6x−32cosh8x)−(ecosh6x−4sinh8x)(4sech24x)
Derivatives of inverse hyperbolic functions
The derivative of inverse hyperbolic functions, such as sinh−1x, can be found using implicit differentiation.
For example, to find the derivative of y=sinh−1x:
x=sinhy
Differentiating both sides with respect to x:
dxd(x)=dxd(sinhy)
1=coshydxdy
dxdy=coshy1
Using the identity cosh2y−sinh2y=1, we have coshy=1+sinh2y. Since sinhy=x, we get coshy=1+x2.
dxdy=1+x21
Therefore, dxd(sinh−1x)=1+x21.
Example 1
Find the derivative of y=cosh−1x with respect to x.
Solution:
Let y=cosh−1x.
x=coshy
Differentiating both sides with respect to x:
1=sinhydxdy
dxdy=sinhy1
Using the identity cosh2y−sinh2y=1, we have sinhy=±cosh2y−1=±x2−1. Since the range of cosh−1 is y≥0, we consider the positive root:
dxdy=x2−11, for x>1
Example 2
Find the derivative of each of the following functions with respect to x:
(a) y=sinh−1(3x)
(b) y=ln(cosh−1x)
Solution:
(a) y=sinh−1(3x)
dxdy=1+(3x)21⋅31=31+9x21=9+x21
(b) y=ln(cosh−1x)
dxdy=cosh−1x1⋅dxd(cosh−1x)=cosh−1x1⋅x2−11=x2−1cosh−1x1
Power series expansions of cosh x and sinh x
The hyperbolic cosine and sine functions can be represented using Maclaurin series. The Maclaurin series for a function f(x) is given by:
f(x)=f(0)+f′(0)x+2!f′′(0)x2+3!f′′′(0)x3+…
Power series expansion of coshx
The power series expansion for coshx is:
coshx=∑n=0∞(2n)!x2n
Proof:
Let y=coshx.
y(0)=cosh0=1
y′(x)=sinhx⇒y′(0)=sinh0=0
y′′(x)=coshx⇒y′′(0)=cosh0=1
y′′′(x)=sinhx⇒y′′′(0)=sinh0=0
y(4)(x)=coshx⇒y(4)(0)=cosh0=1
And so on. Substituting these values into the Maclaurin series:
coshx=1+0x+2!1x2+3!0x3+4!1x4+…
coshx=1+2!x2+4!x4+6!x6+…
Power series expansion of sinhx
The power series expansion for sinhx is:
sinhx=∑n=0∞(2n+1)!x2n+1
Proof:
Let y=sinhx.
y(0)=sinh0=0
y′(x)=coshx⇒y′(0)=cosh0=1
y′′(x)=sinhx⇒y′′(0)=sinh0=0
y′′′(x)=coshx⇒y′′′(0)=cosh0=1
And so on. Substituting these values into the Maclaurin series:
sinhx=0+1x+2!0x2+3!1x3+4!0x4+5!1x5+…
sinhx=x+3!x3+5!x5+…
Example 1
Using the power series expansion of coshx up to the term in x4, approximate the value for cosh1, correct to 4 decimal places.
Solution:
coshx≈1+2!x2+4!x4
cosh1≈1+212+2414=1+0.5+0.041666...≈1.5417
Example 2
Expand the expression sinh3x as a power series as far as the term in x5.
Solution:
sinhx=x+3!x3+5!x5+…
sinh3x=3x+3!(3x)3+5!(3x)5+…
sinh3x=3x+627x3+120243x5+…
sinh3x=3x+29x3+4081x5+…
Example 3
Determine the power series for 41cosh4x−sinh2x as far as the term in x6.
Solution:
41cosh4x=41(1+2!(4x)2+4!(4x)4+6!(4x)6+…)=41+128x2+6144x4+786432x6+…
sinh2x=2x+3!(2x)3+5!(2x)5+6!(2x)6+...=2x+68x3+12032x5+72064x6+...=2x+34x3+154x5+454x6+...
41cosh4x−sinh2x=(41+128x2+6144x4+786432x6+…)−(2x+34x3+154x5+454x6+...)
=41−2x+1281x2−34x3+61441x4−154x5+(7864321−454)x6+...