Using Bernoulli's inequality to prove $e^x ge 1+x$ [closed]
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I need to prove that $e^x ge 1+x$ for every real $x$ by using Bernoulli's inequality.
real-analysis
edited Dec 2 at 14:22
J.G.
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asked Dec 2 at 14:06
Another Noone
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closed as off-topic by amWhy, user302797, RRL, Lord Shark the Unknown, Shailesh Dec 3 at 0:11
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I need to prove that $e^x ge 1+x$ for every real $x$ by using Bernoulli's inequality.
real-analysis
edited Dec 2 at 14:22
J.G.
20.5k21933
asked Dec 2 at 14:06
Another Noone
32
closed as off-topic by amWhy, user302797, RRL, Lord Shark the Unknown, Shailesh Dec 3 at 0:11
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please improve the question by providing additional context, which ideally includes your thoughts on the problem and any attempts you have made to solve it. This information helps others identify where you have difficulties and helps them write answers appropriate to your experience level." – amWhy, user302797, RRL
If this question can be reworded to fit the rules in the help center, please edit the question.
4
Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23
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up vote
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down vote
favorite
I need to prove that $e^x ge 1+x$ for every real $x$ by using Bernoulli's inequality.
real-analysis
edited Dec 2 at 14:22
J.G.
20.5k21933
asked Dec 2 at 14:06
Another Noone
32
I need to prove that $e^x ge 1+x$ for every real $x$ by using Bernoulli's inequality.
real-analysis
real-analysis
edited Dec 2 at 14:22
J.G.
20.5k21933
asked Dec 2 at 14:06
Another Noone
32
edited Dec 2 at 14:22
J.G.
20.5k21933
asked Dec 2 at 14:06
Another Noone
32
edited Dec 2 at 14:22
J.G.
20.5k21933
edited Dec 2 at 14:22
J.G.
20.5k21933
edited Dec 2 at 14:22
J.G.
20.5k21933
20.5k21933
asked Dec 2 at 14:06
Another Noone
32
asked Dec 2 at 14:06
Another Noone
32
asked Dec 2 at 14:06
Another Noone
32
32
closed as off-topic by amWhy, user302797, RRL, Lord Shark the Unknown, Shailesh Dec 3 at 0:11
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please improve the question by providing additional context, which ideally includes your thoughts on the problem and any attempts you have made to solve it. This information helps others identify where you have difficulties and helps them write answers appropriate to your experience level." – amWhy, user302797, RRL
If this question can be reworded to fit the rules in the help center, please edit the question.
closed as off-topic by amWhy, user302797, RRL, Lord Shark the Unknown, Shailesh Dec 3 at 0:11
This question appears to be off-topic. The users who voted to close gave this specific reason:
- "This question is missing context or other details: Please improve the question by providing additional context, which ideally includes your thoughts on the problem and any attempts you have made to solve it. This information helps others identify where you have difficulties and helps them write answers appropriate to your experience level." – amWhy, user302797, RRL
If this question can be reworded to fit the rules in the help center, please edit the question.
4
Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23
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4
Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23
4
4
Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23
Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23
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4 Answers
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2
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Hint:
$$(1+m)^n geq 1+mn$$
From here, let
$$m = frac{x}{n}$$
and recall that $big(1+frac{x}{n}big)^n to e^x$ as $n to infty$.
You can also use the solution proposed above, considering
$$e geq bigg(1+frac{1}{n}bigg)^n implies e^x geq bigg(1+frac{1}{n}bigg)^{nx} geq 1+x$$
and including that
$$bigg(1+frac{1}{n}bigg)^n = {n choose 0}+{n choose 1}bigg(frac{1}{n}bigg)+{n choose 2}bigg(frac{1}{n}bigg)^2+…$$
$$= 1+frac{n!}{1!(n-1)!n}+frac{n!}{2!(n-2)!n^2}+…$$
and since all the terms are contain the same degree of $n$ in the numerator and denominator, $n to infty$ yields
$$= 1+1+frac{1}{2!}+frac{1}{3!}+frac{1}{4!}+… to e$$
answered Dec 2 at 14:18
KM101
3,416417
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
add a comment |
up vote
2
down vote
Since $left(1+frac1nright)^{n}le e$, we have that
$$e^xge left(1+frac1nright)^{xn}stackrel{B.I.}ge 1+nxcdot frac1n=1+x$$
Refer also to the related
- How to prove that $lim_{ntoinfty}big(1+1/nbig)^n$ is equal to e
answered Dec 2 at 14:10
gimusi
90.6k74495
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up vote
1
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Bernoulli's inequality:
1) $(1+y)^n ge 1+ny$, where $n in mathbb{N}$, and $y ge -1$.
Let $x$ be real, then for large enough $n$:
$|x| <n$ , or $|x|/n<1$.
We then have $(1+x/n)^n ge 1+x$.
2) $e^x = lim_{n rightarrow infty}(1+x/n)^n$, $x$ real.
The sequence $(1+x/n)^n$ is increasing
for $n >|x|$. $e^x$ is an upper bound
(Proving that sequence $x_n=(1+x/ n)^n$ is increasing and bounded for $n>|x|$ and therefore the $lim_{n to infty}x_n$ exists).
Finally:
$e^x > (1+x/n)^n >1+x$.
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
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Let the exponential function be defined as
$$exp(x)=e^x=lim_{ntoinfty}Big(1+frac{x}{n}Big)^n$$
Step 1:
First we prove $exp(x)geq 0$ for all $xinmathbb{R}$.
For an arbitrary $xinmathbb{R}$ there is a natural number $n$ such that $|x|<n$, thus $-1<frac{x}{n}<1$. This implies $0<1+frac{x}{n}<2$, thus
$$Big(1+frac{x}{n}Big)^n>0$$
For all $Ngeq n$ we have then
$$Big(1+frac{x}{N}Big)^N>0$$
Thus
$$lim_{Ntoinfty}Big(1+frac{x}{N}Big)^N=e^xgeq 0$$
Step 2: Next we show $e^xgeq 1+x$ for all $xinmathbb{R}$.
- The inequality is obviously true for $xleq -1$, since the right hand side is smaller or equal to zero, but the left hand side is greater or equal to zero.
- Now consider the case $x>-1$. Then for all $ninmathbb{N}$ we have $frac{x}{n}>-1$ and finally we use the Bernoulli's inequality to obtain
$$Big(1+frac{x}{n}Big)^ngeq 1+ncdot frac{x}{n}=1+x$$
Sending $ntoinfty$ you get the result.
answered Dec 2 at 15:38
Fakemistake
1,635815
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4 Answers
4
active
oldest
votes
4 Answers
4
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
2
down vote
accepted
Hint:
$$(1+m)^n geq 1+mn$$
From here, let
$$m = frac{x}{n}$$
and recall that $big(1+frac{x}{n}big)^n to e^x$ as $n to infty$.
You can also use the solution proposed above, considering
$$e geq bigg(1+frac{1}{n}bigg)^n implies e^x geq bigg(1+frac{1}{n}bigg)^{nx} geq 1+x$$
and including that
$$bigg(1+frac{1}{n}bigg)^n = {n choose 0}+{n choose 1}bigg(frac{1}{n}bigg)+{n choose 2}bigg(frac{1}{n}bigg)^2+…$$
$$= 1+frac{n!}{1!(n-1)!n}+frac{n!}{2!(n-2)!n^2}+…$$
and since all the terms are contain the same degree of $n$ in the numerator and denominator, $n to infty$ yields
$$= 1+1+frac{1}{2!}+frac{1}{3!}+frac{1}{4!}+… to e$$
answered Dec 2 at 14:18
KM101
3,416417
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
add a comment |
up vote
2
down vote
accepted
Hint:
$$(1+m)^n geq 1+mn$$
From here, let
$$m = frac{x}{n}$$
and recall that $big(1+frac{x}{n}big)^n to e^x$ as $n to infty$.
You can also use the solution proposed above, considering
$$e geq bigg(1+frac{1}{n}bigg)^n implies e^x geq bigg(1+frac{1}{n}bigg)^{nx} geq 1+x$$
and including that
$$bigg(1+frac{1}{n}bigg)^n = {n choose 0}+{n choose 1}bigg(frac{1}{n}bigg)+{n choose 2}bigg(frac{1}{n}bigg)^2+…$$
$$= 1+frac{n!}{1!(n-1)!n}+frac{n!}{2!(n-2)!n^2}+…$$
and since all the terms are contain the same degree of $n$ in the numerator and denominator, $n to infty$ yields
$$= 1+1+frac{1}{2!}+frac{1}{3!}+frac{1}{4!}+… to e$$
answered Dec 2 at 14:18
KM101
3,416417
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
add a comment |
up vote
2
down vote
accepted
up vote
2
down vote
accepted
Hint:
$$(1+m)^n geq 1+mn$$
From here, let
$$m = frac{x}{n}$$
and recall that $big(1+frac{x}{n}big)^n to e^x$ as $n to infty$.
You can also use the solution proposed above, considering
$$e geq bigg(1+frac{1}{n}bigg)^n implies e^x geq bigg(1+frac{1}{n}bigg)^{nx} geq 1+x$$
and including that
$$bigg(1+frac{1}{n}bigg)^n = {n choose 0}+{n choose 1}bigg(frac{1}{n}bigg)+{n choose 2}bigg(frac{1}{n}bigg)^2+…$$
$$= 1+frac{n!}{1!(n-1)!n}+frac{n!}{2!(n-2)!n^2}+…$$
and since all the terms are contain the same degree of $n$ in the numerator and denominator, $n to infty$ yields
$$= 1+1+frac{1}{2!}+frac{1}{3!}+frac{1}{4!}+… to e$$
answered Dec 2 at 14:18
KM101
3,416417
Hint:
$$(1+m)^n geq 1+mn$$
From here, let
$$m = frac{x}{n}$$
and recall that $big(1+frac{x}{n}big)^n to e^x$ as $n to infty$.
You can also use the solution proposed above, considering
$$e geq bigg(1+frac{1}{n}bigg)^n implies e^x geq bigg(1+frac{1}{n}bigg)^{nx} geq 1+x$$
and including that
$$bigg(1+frac{1}{n}bigg)^n = {n choose 0}+{n choose 1}bigg(frac{1}{n}bigg)+{n choose 2}bigg(frac{1}{n}bigg)^2+…$$
$$= 1+frac{n!}{1!(n-1)!n}+frac{n!}{2!(n-2)!n^2}+…$$
and since all the terms are contain the same degree of $n$ in the numerator and denominator, $n to infty$ yields
$$= 1+1+frac{1}{2!}+frac{1}{3!}+frac{1}{4!}+… to e$$
answered Dec 2 at 14:18
KM101
3,416417
edited Dec 2 at 14:49
answered Dec 2 at 14:18
KM101
3,416417
answered Dec 2 at 14:18
KM101
3,416417
answered Dec 2 at 14:18
KM101
3,416417
3,416417
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
add a comment |
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
@Anither Noone I’m not sure what you can or can’t assume. If you can assume $big(1+frac{1}{n}big)^n to e$ as $n to infty$, then gimusi’s solution seems sufficient.
– KM101
Dec 2 at 14:35
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
I thought so to, but I think Ill just inlcude the reference to the respective power series in my solution
– Another Noone
Dec 2 at 14:40
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
Of course, you could prove the limit for $e$ using binomial expansion and taking $n to infty$, leading to the power series for $e$.
– KM101
Dec 2 at 14:42
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
If I use this solution, can i then prove that for x<1 e^x <= 1/(1-x) ?
– Another Noone
Dec 2 at 15:10
add a comment |
up vote
2
down vote
Since $left(1+frac1nright)^{n}le e$, we have that
$$e^xge left(1+frac1nright)^{xn}stackrel{B.I.}ge 1+nxcdot frac1n=1+x$$
Refer also to the related
- How to prove that $lim_{ntoinfty}big(1+1/nbig)^n$ is equal to e
answered Dec 2 at 14:10
gimusi
90.6k74495
add a comment |
up vote
2
down vote
Since $left(1+frac1nright)^{n}le e$, we have that
$$e^xge left(1+frac1nright)^{xn}stackrel{B.I.}ge 1+nxcdot frac1n=1+x$$
Refer also to the related
- How to prove that $lim_{ntoinfty}big(1+1/nbig)^n$ is equal to e
answered Dec 2 at 14:10
gimusi
90.6k74495
add a comment |
up vote
2
down vote
up vote
2
down vote
Since $left(1+frac1nright)^{n}le e$, we have that
$$e^xge left(1+frac1nright)^{xn}stackrel{B.I.}ge 1+nxcdot frac1n=1+x$$
Refer also to the related
- How to prove that $lim_{ntoinfty}big(1+1/nbig)^n$ is equal to e
answered Dec 2 at 14:10
gimusi
90.6k74495
Since $left(1+frac1nright)^{n}le e$, we have that
$$e^xge left(1+frac1nright)^{xn}stackrel{B.I.}ge 1+nxcdot frac1n=1+x$$
Refer also to the related
- How to prove that $lim_{ntoinfty}big(1+1/nbig)^n$ is equal to e
answered Dec 2 at 14:10
gimusi
90.6k74495
edited Dec 2 at 15:31
answered Dec 2 at 14:10
gimusi
90.6k74495
answered Dec 2 at 14:10
gimusi
90.6k74495
answered Dec 2 at 14:10
gimusi
90.6k74495
90.6k74495
add a comment |
add a comment |
up vote
1
down vote
Bernoulli's inequality:
1) $(1+y)^n ge 1+ny$, where $n in mathbb{N}$, and $y ge -1$.
Let $x$ be real, then for large enough $n$:
$|x| <n$ , or $|x|/n<1$.
We then have $(1+x/n)^n ge 1+x$.
2) $e^x = lim_{n rightarrow infty}(1+x/n)^n$, $x$ real.
The sequence $(1+x/n)^n$ is increasing
for $n >|x|$. $e^x$ is an upper bound
(Proving that sequence $x_n=(1+x/ n)^n$ is increasing and bounded for $n>|x|$ and therefore the $lim_{n to infty}x_n$ exists).
Finally:
$e^x > (1+x/n)^n >1+x$.
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
add a comment |
up vote
1
down vote
Bernoulli's inequality:
1) $(1+y)^n ge 1+ny$, where $n in mathbb{N}$, and $y ge -1$.
Let $x$ be real, then for large enough $n$:
$|x| <n$ , or $|x|/n<1$.
We then have $(1+x/n)^n ge 1+x$.
2) $e^x = lim_{n rightarrow infty}(1+x/n)^n$, $x$ real.
The sequence $(1+x/n)^n$ is increasing
for $n >|x|$. $e^x$ is an upper bound
(Proving that sequence $x_n=(1+x/ n)^n$ is increasing and bounded for $n>|x|$ and therefore the $lim_{n to infty}x_n$ exists).
Finally:
$e^x > (1+x/n)^n >1+x$.
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
add a comment |
up vote
1
down vote
up vote
1
down vote
Bernoulli's inequality:
1) $(1+y)^n ge 1+ny$, where $n in mathbb{N}$, and $y ge -1$.
Let $x$ be real, then for large enough $n$:
$|x| <n$ , or $|x|/n<1$.
We then have $(1+x/n)^n ge 1+x$.
2) $e^x = lim_{n rightarrow infty}(1+x/n)^n$, $x$ real.
The sequence $(1+x/n)^n$ is increasing
for $n >|x|$. $e^x$ is an upper bound
(Proving that sequence $x_n=(1+x/ n)^n$ is increasing and bounded for $n>|x|$ and therefore the $lim_{n to infty}x_n$ exists).
Finally:
$e^x > (1+x/n)^n >1+x$.
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
Bernoulli's inequality:
1) $(1+y)^n ge 1+ny$, where $n in mathbb{N}$, and $y ge -1$.
Let $x$ be real, then for large enough $n$:
$|x| <n$ , or $|x|/n<1$.
We then have $(1+x/n)^n ge 1+x$.
2) $e^x = lim_{n rightarrow infty}(1+x/n)^n$, $x$ real.
The sequence $(1+x/n)^n$ is increasing
for $n >|x|$. $e^x$ is an upper bound
(Proving that sequence $x_n=(1+x/ n)^n$ is increasing and bounded for $n>|x|$ and therefore the $lim_{n to infty}x_n$ exists).
Finally:
$e^x > (1+x/n)^n >1+x$.
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
edited Dec 2 at 17:26
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
answered Dec 2 at 15:00
Peter Szilas
10.4k2720
10.4k2720
add a comment |
add a comment |
up vote
0
down vote
Let the exponential function be defined as
$$exp(x)=e^x=lim_{ntoinfty}Big(1+frac{x}{n}Big)^n$$
Step 1:
First we prove $exp(x)geq 0$ for all $xinmathbb{R}$.
For an arbitrary $xinmathbb{R}$ there is a natural number $n$ such that $|x|<n$, thus $-1<frac{x}{n}<1$. This implies $0<1+frac{x}{n}<2$, thus
$$Big(1+frac{x}{n}Big)^n>0$$
For all $Ngeq n$ we have then
$$Big(1+frac{x}{N}Big)^N>0$$
Thus
$$lim_{Ntoinfty}Big(1+frac{x}{N}Big)^N=e^xgeq 0$$
Step 2: Next we show $e^xgeq 1+x$ for all $xinmathbb{R}$.
- The inequality is obviously true for $xleq -1$, since the right hand side is smaller or equal to zero, but the left hand side is greater or equal to zero.
- Now consider the case $x>-1$. Then for all $ninmathbb{N}$ we have $frac{x}{n}>-1$ and finally we use the Bernoulli's inequality to obtain
$$Big(1+frac{x}{n}Big)^ngeq 1+ncdot frac{x}{n}=1+x$$
Sending $ntoinfty$ you get the result.
answered Dec 2 at 15:38
Fakemistake
1,635815
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up vote
0
down vote
Let the exponential function be defined as
$$exp(x)=e^x=lim_{ntoinfty}Big(1+frac{x}{n}Big)^n$$
Step 1:
First we prove $exp(x)geq 0$ for all $xinmathbb{R}$.
For an arbitrary $xinmathbb{R}$ there is a natural number $n$ such that $|x|<n$, thus $-1<frac{x}{n}<1$. This implies $0<1+frac{x}{n}<2$, thus
$$Big(1+frac{x}{n}Big)^n>0$$
For all $Ngeq n$ we have then
$$Big(1+frac{x}{N}Big)^N>0$$
Thus
$$lim_{Ntoinfty}Big(1+frac{x}{N}Big)^N=e^xgeq 0$$
Step 2: Next we show $e^xgeq 1+x$ for all $xinmathbb{R}$.
- The inequality is obviously true for $xleq -1$, since the right hand side is smaller or equal to zero, but the left hand side is greater or equal to zero.
- Now consider the case $x>-1$. Then for all $ninmathbb{N}$ we have $frac{x}{n}>-1$ and finally we use the Bernoulli's inequality to obtain
$$Big(1+frac{x}{n}Big)^ngeq 1+ncdot frac{x}{n}=1+x$$
Sending $ntoinfty$ you get the result.
answered Dec 2 at 15:38
Fakemistake
1,635815
add a comment |
up vote
0
down vote
up vote
0
down vote
Let the exponential function be defined as
$$exp(x)=e^x=lim_{ntoinfty}Big(1+frac{x}{n}Big)^n$$
Step 1:
First we prove $exp(x)geq 0$ for all $xinmathbb{R}$.
For an arbitrary $xinmathbb{R}$ there is a natural number $n$ such that $|x|<n$, thus $-1<frac{x}{n}<1$. This implies $0<1+frac{x}{n}<2$, thus
$$Big(1+frac{x}{n}Big)^n>0$$
For all $Ngeq n$ we have then
$$Big(1+frac{x}{N}Big)^N>0$$
Thus
$$lim_{Ntoinfty}Big(1+frac{x}{N}Big)^N=e^xgeq 0$$
Step 2: Next we show $e^xgeq 1+x$ for all $xinmathbb{R}$.
- The inequality is obviously true for $xleq -1$, since the right hand side is smaller or equal to zero, but the left hand side is greater or equal to zero.
- Now consider the case $x>-1$. Then for all $ninmathbb{N}$ we have $frac{x}{n}>-1$ and finally we use the Bernoulli's inequality to obtain
$$Big(1+frac{x}{n}Big)^ngeq 1+ncdot frac{x}{n}=1+x$$
Sending $ntoinfty$ you get the result.
answered Dec 2 at 15:38
Fakemistake
1,635815
Let the exponential function be defined as
$$exp(x)=e^x=lim_{ntoinfty}Big(1+frac{x}{n}Big)^n$$
Step 1:
First we prove $exp(x)geq 0$ for all $xinmathbb{R}$.
For an arbitrary $xinmathbb{R}$ there is a natural number $n$ such that $|x|<n$, thus $-1<frac{x}{n}<1$. This implies $0<1+frac{x}{n}<2$, thus
$$Big(1+frac{x}{n}Big)^n>0$$
For all $Ngeq n$ we have then
$$Big(1+frac{x}{N}Big)^N>0$$
Thus
$$lim_{Ntoinfty}Big(1+frac{x}{N}Big)^N=e^xgeq 0$$
Step 2: Next we show $e^xgeq 1+x$ for all $xinmathbb{R}$.
- The inequality is obviously true for $xleq -1$, since the right hand side is smaller or equal to zero, but the left hand side is greater or equal to zero.
- Now consider the case $x>-1$. Then for all $ninmathbb{N}$ we have $frac{x}{n}>-1$ and finally we use the Bernoulli's inequality to obtain
$$Big(1+frac{x}{n}Big)^ngeq 1+ncdot frac{x}{n}=1+x$$
Sending $ntoinfty$ you get the result.
answered Dec 2 at 15:38
Fakemistake
1,635815
answered Dec 2 at 15:38
Fakemistake
1,635815
answered Dec 2 at 15:38
Fakemistake
1,635815
answered Dec 2 at 15:38
Fakemistake
1,635815
1,635815
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Possible duplicate of Simplest or nicest proof that $1+x le e^x$
– John11
Dec 2 at 14:23