Prove that a horizontal asymptote can never be crossed
$begingroup$
This is a lot simpler of a problem than others posted here, but I was bored in class and decided to work out why a horizontal asymptote exists. Bear in mind that I am still fairly low on the “math ladder.”
So to accomplish this I worked off of one example equation that could be made into a general case later on, with the chosen one being $$y = frac{2x+6}{x+1}$$
Now, proving any vertical asymptote is simple (by definition it creates a “divide by zero” error when plugged into the equation), but a horizontal asymptote “proof” requires some manipulation. So, doing a little shuffling of the equation to isolate the variables slightly... $$y = frac{x(2+frac{6}{x})}{x(1+frac{1}{x})}$$
The $x$ on the top and bottom of the function will cancel out, and we are left with $$y = frac{2+frac{6}{x}}{1+frac{1}{x}}$$
With a little more rearranging by multiplying the function by the denominator, you get $$yleft(1+frac{1}{x}right) = 2+frac{6}{x}$$
You likely see what is wrong with this, but let’s distribute the $y$ to simplify further: $$y+frac{y}{x} = 2+frac{6}{x}$$
Now everything is ready to plug in. Say that there is a value that corresponds to $y = 2$ (the horizontal asymptote of this graph, found by dividing $p$ by $q$, or $2/1$, because $operatorname{deg} p = operatorname{deg} q$). Then the equation should be able to be used to find this value. However, if $2$ is substituted for $y$...
$$2+frac{2}{x} = 2+frac{6}{x}$$
$$frac{2}{x} = frac{6}{x}$$
$$2 = 6$$
Therefore $y$ cannot be equal to $2$. I believe that is referred to as a “proof by contradiction” but correct me if I’m wrong. Or if the whole proof is wrong, for that matter. Anyways, I’d love to generalize this but I’m hitting a roadblock due to not knowing of a comprehensive standard form for all rational expressions. I’ve tried it on numerous equations but I’m not sure how to explain what I think is going on. Every time you plug the asymptote into the reworked equation you end up with a contradiction, and any other numbers (minus holes) returns a value that can be found on the graph.
Can anyone help with this? I just felt like sharing this little 10 minute project because it intrigued me, but being able to generalize it to see what’s going on between each variable and coefficient (specifically, how/why the leading terms and degrees affect the H.A) would be helpful for overall understanding of the topic. Thanks!
proof-verification
New contributor
$endgroup$
|
show 1 more comment
$begingroup$
This is a lot simpler of a problem than others posted here, but I was bored in class and decided to work out why a horizontal asymptote exists. Bear in mind that I am still fairly low on the “math ladder.”
So to accomplish this I worked off of one example equation that could be made into a general case later on, with the chosen one being $$y = frac{2x+6}{x+1}$$
Now, proving any vertical asymptote is simple (by definition it creates a “divide by zero” error when plugged into the equation), but a horizontal asymptote “proof” requires some manipulation. So, doing a little shuffling of the equation to isolate the variables slightly... $$y = frac{x(2+frac{6}{x})}{x(1+frac{1}{x})}$$
The $x$ on the top and bottom of the function will cancel out, and we are left with $$y = frac{2+frac{6}{x}}{1+frac{1}{x}}$$
With a little more rearranging by multiplying the function by the denominator, you get $$yleft(1+frac{1}{x}right) = 2+frac{6}{x}$$
You likely see what is wrong with this, but let’s distribute the $y$ to simplify further: $$y+frac{y}{x} = 2+frac{6}{x}$$
Now everything is ready to plug in. Say that there is a value that corresponds to $y = 2$ (the horizontal asymptote of this graph, found by dividing $p$ by $q$, or $2/1$, because $operatorname{deg} p = operatorname{deg} q$). Then the equation should be able to be used to find this value. However, if $2$ is substituted for $y$...
$$2+frac{2}{x} = 2+frac{6}{x}$$
$$frac{2}{x} = frac{6}{x}$$
$$2 = 6$$
Therefore $y$ cannot be equal to $2$. I believe that is referred to as a “proof by contradiction” but correct me if I’m wrong. Or if the whole proof is wrong, for that matter. Anyways, I’d love to generalize this but I’m hitting a roadblock due to not knowing of a comprehensive standard form for all rational expressions. I’ve tried it on numerous equations but I’m not sure how to explain what I think is going on. Every time you plug the asymptote into the reworked equation you end up with a contradiction, and any other numbers (minus holes) returns a value that can be found on the graph.
Can anyone help with this? I just felt like sharing this little 10 minute project because it intrigued me, but being able to generalize it to see what’s going on between each variable and coefficient (specifically, how/why the leading terms and degrees affect the H.A) would be helpful for overall understanding of the topic. Thanks!
proof-verification
New contributor
$endgroup$
$begingroup$
In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
$endgroup$
– Jose27
1 hour ago
$begingroup$
For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
$endgroup$
– 1123581321
1 hour ago
1
$begingroup$
You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
$endgroup$
– Bertrand Wittgenstein's Ghost
1 hour ago
|
show 1 more comment
$begingroup$
This is a lot simpler of a problem than others posted here, but I was bored in class and decided to work out why a horizontal asymptote exists. Bear in mind that I am still fairly low on the “math ladder.”
So to accomplish this I worked off of one example equation that could be made into a general case later on, with the chosen one being $$y = frac{2x+6}{x+1}$$
Now, proving any vertical asymptote is simple (by definition it creates a “divide by zero” error when plugged into the equation), but a horizontal asymptote “proof” requires some manipulation. So, doing a little shuffling of the equation to isolate the variables slightly... $$y = frac{x(2+frac{6}{x})}{x(1+frac{1}{x})}$$
The $x$ on the top and bottom of the function will cancel out, and we are left with $$y = frac{2+frac{6}{x}}{1+frac{1}{x}}$$
With a little more rearranging by multiplying the function by the denominator, you get $$yleft(1+frac{1}{x}right) = 2+frac{6}{x}$$
You likely see what is wrong with this, but let’s distribute the $y$ to simplify further: $$y+frac{y}{x} = 2+frac{6}{x}$$
Now everything is ready to plug in. Say that there is a value that corresponds to $y = 2$ (the horizontal asymptote of this graph, found by dividing $p$ by $q$, or $2/1$, because $operatorname{deg} p = operatorname{deg} q$). Then the equation should be able to be used to find this value. However, if $2$ is substituted for $y$...
$$2+frac{2}{x} = 2+frac{6}{x}$$
$$frac{2}{x} = frac{6}{x}$$
$$2 = 6$$
Therefore $y$ cannot be equal to $2$. I believe that is referred to as a “proof by contradiction” but correct me if I’m wrong. Or if the whole proof is wrong, for that matter. Anyways, I’d love to generalize this but I’m hitting a roadblock due to not knowing of a comprehensive standard form for all rational expressions. I’ve tried it on numerous equations but I’m not sure how to explain what I think is going on. Every time you plug the asymptote into the reworked equation you end up with a contradiction, and any other numbers (minus holes) returns a value that can be found on the graph.
Can anyone help with this? I just felt like sharing this little 10 minute project because it intrigued me, but being able to generalize it to see what’s going on between each variable and coefficient (specifically, how/why the leading terms and degrees affect the H.A) would be helpful for overall understanding of the topic. Thanks!
proof-verification
New contributor
$endgroup$
This is a lot simpler of a problem than others posted here, but I was bored in class and decided to work out why a horizontal asymptote exists. Bear in mind that I am still fairly low on the “math ladder.”
So to accomplish this I worked off of one example equation that could be made into a general case later on, with the chosen one being $$y = frac{2x+6}{x+1}$$
Now, proving any vertical asymptote is simple (by definition it creates a “divide by zero” error when plugged into the equation), but a horizontal asymptote “proof” requires some manipulation. So, doing a little shuffling of the equation to isolate the variables slightly... $$y = frac{x(2+frac{6}{x})}{x(1+frac{1}{x})}$$
The $x$ on the top and bottom of the function will cancel out, and we are left with $$y = frac{2+frac{6}{x}}{1+frac{1}{x}}$$
With a little more rearranging by multiplying the function by the denominator, you get $$yleft(1+frac{1}{x}right) = 2+frac{6}{x}$$
You likely see what is wrong with this, but let’s distribute the $y$ to simplify further: $$y+frac{y}{x} = 2+frac{6}{x}$$
Now everything is ready to plug in. Say that there is a value that corresponds to $y = 2$ (the horizontal asymptote of this graph, found by dividing $p$ by $q$, or $2/1$, because $operatorname{deg} p = operatorname{deg} q$). Then the equation should be able to be used to find this value. However, if $2$ is substituted for $y$...
$$2+frac{2}{x} = 2+frac{6}{x}$$
$$frac{2}{x} = frac{6}{x}$$
$$2 = 6$$
Therefore $y$ cannot be equal to $2$. I believe that is referred to as a “proof by contradiction” but correct me if I’m wrong. Or if the whole proof is wrong, for that matter. Anyways, I’d love to generalize this but I’m hitting a roadblock due to not knowing of a comprehensive standard form for all rational expressions. I’ve tried it on numerous equations but I’m not sure how to explain what I think is going on. Every time you plug the asymptote into the reworked equation you end up with a contradiction, and any other numbers (minus holes) returns a value that can be found on the graph.
Can anyone help with this? I just felt like sharing this little 10 minute project because it intrigued me, but being able to generalize it to see what’s going on between each variable and coefficient (specifically, how/why the leading terms and degrees affect the H.A) would be helpful for overall understanding of the topic. Thanks!
proof-verification
proof-verification
New contributor
New contributor
edited 1 hour ago
Robert Howard
2,2783935
2,2783935
New contributor
asked 1 hour ago
Jake RJake R
162
162
New contributor
New contributor
$begingroup$
In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
$endgroup$
– Jose27
1 hour ago
$begingroup$
For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
$endgroup$
– 1123581321
1 hour ago
1
$begingroup$
You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
$endgroup$
– Bertrand Wittgenstein's Ghost
1 hour ago
|
show 1 more comment
$begingroup$
In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
$endgroup$
– Jose27
1 hour ago
$begingroup$
For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
$endgroup$
– 1123581321
1 hour ago
1
$begingroup$
You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
$endgroup$
– 1123581321
1 hour ago
2
$begingroup$
This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
$endgroup$
– Bertrand Wittgenstein's Ghost
1 hour ago
$begingroup$
In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
$endgroup$
– 1123581321
1 hour ago
$begingroup$
In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
$endgroup$
– 1123581321
1 hour ago
2
2
$begingroup$
What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
$endgroup$
– Jose27
1 hour ago
$begingroup$
What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
$endgroup$
– Jose27
1 hour ago
$begingroup$
For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
$endgroup$
– 1123581321
1 hour ago
$begingroup$
For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
$endgroup$
– 1123581321
1 hour ago
1
1
$begingroup$
You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
$endgroup$
– 1123581321
1 hour ago
$begingroup$
You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
$endgroup$
– 1123581321
1 hour ago
2
2
$begingroup$
This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
$endgroup$
– Bertrand Wittgenstein's Ghost
1 hour ago
$begingroup$
This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
$endgroup$
– Bertrand Wittgenstein's Ghost
1 hour ago
|
show 1 more comment
2 Answers
2
active
oldest
votes
$begingroup$
You indeed proved that your function never crosses the asymptote $y=2$. Specifically, you proved following statement
There does not exists $xin mathbb{R}$ such that
$$
frac{2x+6}{x+1} = 2.
$$
To so this, you indeed used a "proof by contradiction". If there exists a number $x$ such that
$$
frac{2x+6}{x+1} = 2.
$$
then
$$
2x+6 = 2(x+1)implies 6=2
$$
which is absurd.
But is what you proved sufficient to conclude that the function has a horizontal asymptote described by the line $y=2$? Let's take a look at a different function;
$$
y = frac{x^2+1}{x^2}.
$$
For this function, there does not exist a number $x$ such that
$$
frac{x^2+1}{x^2} = 0.
$$
But this does not mean that the horizontal asymptote is described by $y=0$. Your horizontal asymptote should instead by the line $y=1$.
Ask yourself the following: how would you got about defining a horizontal asymptote? What properties do you think it should have?
Usually, we want an asymptote to somehow capture the behaviour of the function as $x$ gets very large. If you want more information on how to make this statement precise, let me know in the comments and I can add detail.
$endgroup$
add a comment |
$begingroup$
Let's stick to rational functions, even if it's not explicitly mentioned that this is what you want to use. So we want to construct such function $f(x)$, that has some asymptote at $pminfty$ and that you cross this asymptote. How would be approaching this? First, note that we can choose $f(pminfty)=0$. If you want a different asymptote, just add a constant.
So we write $$f(x)=frac{P(x)}{Q(x)}$$ where $P$ and $Q$ are polynomials. If the degree of $Q$ is greater than the degree of $P$, this asymptotically will go to $0$. For simplicity, just choose $Q(x)=x^n$. Now if we choose $n-1$ different real, non-zero numbers $x_1, x_2,...,x_{n-1}$, we can construct $P(x)=(x-x_1)(x-x_2)...(x-x_n-1)$, a polynomial with degree $n-1$, with $n-1$ real, non-zero roots. With these choices, $f(x)$ defined above has a horizontal asymptote, and the function is crossing the horizontal line at $n-1$ different points.
$endgroup$
add a comment |
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2 Answers
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2 Answers
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$begingroup$
You indeed proved that your function never crosses the asymptote $y=2$. Specifically, you proved following statement
There does not exists $xin mathbb{R}$ such that
$$
frac{2x+6}{x+1} = 2.
$$
To so this, you indeed used a "proof by contradiction". If there exists a number $x$ such that
$$
frac{2x+6}{x+1} = 2.
$$
then
$$
2x+6 = 2(x+1)implies 6=2
$$
which is absurd.
But is what you proved sufficient to conclude that the function has a horizontal asymptote described by the line $y=2$? Let's take a look at a different function;
$$
y = frac{x^2+1}{x^2}.
$$
For this function, there does not exist a number $x$ such that
$$
frac{x^2+1}{x^2} = 0.
$$
But this does not mean that the horizontal asymptote is described by $y=0$. Your horizontal asymptote should instead by the line $y=1$.
Ask yourself the following: how would you got about defining a horizontal asymptote? What properties do you think it should have?
Usually, we want an asymptote to somehow capture the behaviour of the function as $x$ gets very large. If you want more information on how to make this statement precise, let me know in the comments and I can add detail.
$endgroup$
add a comment |
$begingroup$
You indeed proved that your function never crosses the asymptote $y=2$. Specifically, you proved following statement
There does not exists $xin mathbb{R}$ such that
$$
frac{2x+6}{x+1} = 2.
$$
To so this, you indeed used a "proof by contradiction". If there exists a number $x$ such that
$$
frac{2x+6}{x+1} = 2.
$$
then
$$
2x+6 = 2(x+1)implies 6=2
$$
which is absurd.
But is what you proved sufficient to conclude that the function has a horizontal asymptote described by the line $y=2$? Let's take a look at a different function;
$$
y = frac{x^2+1}{x^2}.
$$
For this function, there does not exist a number $x$ such that
$$
frac{x^2+1}{x^2} = 0.
$$
But this does not mean that the horizontal asymptote is described by $y=0$. Your horizontal asymptote should instead by the line $y=1$.
Ask yourself the following: how would you got about defining a horizontal asymptote? What properties do you think it should have?
Usually, we want an asymptote to somehow capture the behaviour of the function as $x$ gets very large. If you want more information on how to make this statement precise, let me know in the comments and I can add detail.
$endgroup$
add a comment |
$begingroup$
You indeed proved that your function never crosses the asymptote $y=2$. Specifically, you proved following statement
There does not exists $xin mathbb{R}$ such that
$$
frac{2x+6}{x+1} = 2.
$$
To so this, you indeed used a "proof by contradiction". If there exists a number $x$ such that
$$
frac{2x+6}{x+1} = 2.
$$
then
$$
2x+6 = 2(x+1)implies 6=2
$$
which is absurd.
But is what you proved sufficient to conclude that the function has a horizontal asymptote described by the line $y=2$? Let's take a look at a different function;
$$
y = frac{x^2+1}{x^2}.
$$
For this function, there does not exist a number $x$ such that
$$
frac{x^2+1}{x^2} = 0.
$$
But this does not mean that the horizontal asymptote is described by $y=0$. Your horizontal asymptote should instead by the line $y=1$.
Ask yourself the following: how would you got about defining a horizontal asymptote? What properties do you think it should have?
Usually, we want an asymptote to somehow capture the behaviour of the function as $x$ gets very large. If you want more information on how to make this statement precise, let me know in the comments and I can add detail.
$endgroup$
You indeed proved that your function never crosses the asymptote $y=2$. Specifically, you proved following statement
There does not exists $xin mathbb{R}$ such that
$$
frac{2x+6}{x+1} = 2.
$$
To so this, you indeed used a "proof by contradiction". If there exists a number $x$ such that
$$
frac{2x+6}{x+1} = 2.
$$
then
$$
2x+6 = 2(x+1)implies 6=2
$$
which is absurd.
But is what you proved sufficient to conclude that the function has a horizontal asymptote described by the line $y=2$? Let's take a look at a different function;
$$
y = frac{x^2+1}{x^2}.
$$
For this function, there does not exist a number $x$ such that
$$
frac{x^2+1}{x^2} = 0.
$$
But this does not mean that the horizontal asymptote is described by $y=0$. Your horizontal asymptote should instead by the line $y=1$.
Ask yourself the following: how would you got about defining a horizontal asymptote? What properties do you think it should have?
Usually, we want an asymptote to somehow capture the behaviour of the function as $x$ gets very large. If you want more information on how to make this statement precise, let me know in the comments and I can add detail.
edited 1 hour ago
answered 1 hour ago
QuokaQuoka
1,538316
1,538316
add a comment |
add a comment |
$begingroup$
Let's stick to rational functions, even if it's not explicitly mentioned that this is what you want to use. So we want to construct such function $f(x)$, that has some asymptote at $pminfty$ and that you cross this asymptote. How would be approaching this? First, note that we can choose $f(pminfty)=0$. If you want a different asymptote, just add a constant.
So we write $$f(x)=frac{P(x)}{Q(x)}$$ where $P$ and $Q$ are polynomials. If the degree of $Q$ is greater than the degree of $P$, this asymptotically will go to $0$. For simplicity, just choose $Q(x)=x^n$. Now if we choose $n-1$ different real, non-zero numbers $x_1, x_2,...,x_{n-1}$, we can construct $P(x)=(x-x_1)(x-x_2)...(x-x_n-1)$, a polynomial with degree $n-1$, with $n-1$ real, non-zero roots. With these choices, $f(x)$ defined above has a horizontal asymptote, and the function is crossing the horizontal line at $n-1$ different points.
$endgroup$
add a comment |
$begingroup$
Let's stick to rational functions, even if it's not explicitly mentioned that this is what you want to use. So we want to construct such function $f(x)$, that has some asymptote at $pminfty$ and that you cross this asymptote. How would be approaching this? First, note that we can choose $f(pminfty)=0$. If you want a different asymptote, just add a constant.
So we write $$f(x)=frac{P(x)}{Q(x)}$$ where $P$ and $Q$ are polynomials. If the degree of $Q$ is greater than the degree of $P$, this asymptotically will go to $0$. For simplicity, just choose $Q(x)=x^n$. Now if we choose $n-1$ different real, non-zero numbers $x_1, x_2,...,x_{n-1}$, we can construct $P(x)=(x-x_1)(x-x_2)...(x-x_n-1)$, a polynomial with degree $n-1$, with $n-1$ real, non-zero roots. With these choices, $f(x)$ defined above has a horizontal asymptote, and the function is crossing the horizontal line at $n-1$ different points.
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add a comment |
$begingroup$
Let's stick to rational functions, even if it's not explicitly mentioned that this is what you want to use. So we want to construct such function $f(x)$, that has some asymptote at $pminfty$ and that you cross this asymptote. How would be approaching this? First, note that we can choose $f(pminfty)=0$. If you want a different asymptote, just add a constant.
So we write $$f(x)=frac{P(x)}{Q(x)}$$ where $P$ and $Q$ are polynomials. If the degree of $Q$ is greater than the degree of $P$, this asymptotically will go to $0$. For simplicity, just choose $Q(x)=x^n$. Now if we choose $n-1$ different real, non-zero numbers $x_1, x_2,...,x_{n-1}$, we can construct $P(x)=(x-x_1)(x-x_2)...(x-x_n-1)$, a polynomial with degree $n-1$, with $n-1$ real, non-zero roots. With these choices, $f(x)$ defined above has a horizontal asymptote, and the function is crossing the horizontal line at $n-1$ different points.
$endgroup$
Let's stick to rational functions, even if it's not explicitly mentioned that this is what you want to use. So we want to construct such function $f(x)$, that has some asymptote at $pminfty$ and that you cross this asymptote. How would be approaching this? First, note that we can choose $f(pminfty)=0$. If you want a different asymptote, just add a constant.
So we write $$f(x)=frac{P(x)}{Q(x)}$$ where $P$ and $Q$ are polynomials. If the degree of $Q$ is greater than the degree of $P$, this asymptotically will go to $0$. For simplicity, just choose $Q(x)=x^n$. Now if we choose $n-1$ different real, non-zero numbers $x_1, x_2,...,x_{n-1}$, we can construct $P(x)=(x-x_1)(x-x_2)...(x-x_n-1)$, a polynomial with degree $n-1$, with $n-1$ real, non-zero roots. With these choices, $f(x)$ defined above has a horizontal asymptote, and the function is crossing the horizontal line at $n-1$ different points.
answered 1 hour ago
AndreiAndrei
13.2k21230
13.2k21230
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Jake R is a new contributor. Be nice, and check out our Code of Conduct.
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Jake R is a new contributor. Be nice, and check out our Code of Conduct.
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In factoring out the $x$ in the second equation, you're assuming that $x neq 0$. You may need to consider what happens at this point.
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– 1123581321
1 hour ago
2
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What about $y=frac{x}{1+x^2}$ which has a horizontal asymptote $y=0$, but it attains this value at $x=0$.
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– Jose27
1 hour ago
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For any rational function where the numerator and denominator are both linear, the horizontal asymptote can be found easily: $y = frac{ax + b}{cx + d} = frac{a + b/x}{c + d/x}$, which tends to $frac{a}{c}$ as $x$ tends to infinity.
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– 1123581321
1 hour ago
1
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You can reach the conclusion that $y$ cannot be equal to 2 just by looking at the 3rd equation (since $frac{1}{x}$ cannot be zero).
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– 1123581321
1 hour ago
2
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This is unnecessarily complicated. Solve for $x$ and you will get this: $x=frac{6-y}{y-2}$. Which implies the function is discontinuous at $y=2$ i.e. horizontal asymptote. QED.
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– Bertrand Wittgenstein's Ghost
1 hour ago