Understanding Calculus: Derivatives, Tangents, and Slopes

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Discussion Overview

The discussion revolves around the concept of derivatives in calculus, specifically focusing on what it means to differentiate a function, the geometric interpretations of derivatives, and their applications in physics. Participants explore the relationship between secant and tangent lines, as well as the conditions under which calculus can be applied in advanced physics problems.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • Some participants propose that differentiating a function provides an instantaneous solution related to the function's behavior with respect to another axis.
  • Others argue that the derivative represents the slope of the tangent line to the graph of the function.
  • A participant questions whether the ratio of the difference in Y-values to the difference in X-values can be interpreted as the area under the curve.
  • Some participants clarify that the ratio discussed is related to the slope of the secant line, not the tangent line.
  • There is a discussion about the geometric interpretation of the derivative and the limiting process involved in calculating it.
  • One participant expresses confusion about the relationship between the tangent, secant lines, and the concept of slope.
  • Another participant emphasizes the importance of understanding the secant line's slope before discussing tangent lines.

Areas of Agreement / Disagreement

Participants do not reach a consensus on all points, particularly regarding the interpretations of the derivative and the relationships between secant and tangent lines. There are multiple competing views and some confusion remains about the concepts discussed.

Contextual Notes

Some participants express uncertainty about the definitions and interpretations of key terms, such as tangent and secant lines, and the conditions under which calculus can be applied in physics problems. The discussion highlights the need for clarity in understanding these concepts.

zeromodz
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Okay, I am new to calculus so can you guys just explain something to me.

What is exactly are you doing to a function when you differentiate or take the derivative of it? I thought that when you do that, you make an instantaneous solution to where something is at all times with respect to the other axis. Is that correct?

Also, whenever you see calculus in advanced physics, I don't understand. You can only use indefinite integrals and derivatives when you have a valid function right? So all these advanced physics problems need functions to go along with them right?

Thank you guys!
 
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What is exactly are you doing to a function when you differentiate or take the derivative of it? I thought that when you do that, you make an instantaneous solution to where something is at all times with respect to the other axis. Is that correct?

Hmm..

Try to formulate what the following quantity is, for non-zero h:
\frac{f(x+h)-f(x)}{h}

Hint:
Draw an arbitray graph, pick two points on the x-axis ("x" and "x+h"), and think of h=(x+h)-x
 
arildno said:
Hmm..

Try to formulate what the following quantity is, for non-zero h:
\frac{f(x+h)-f(x)}{h}

Hint:
Draw an arbitray graph, pick two points on the x-axis ("x" and "x+h"), and think of h=(x+h)-x

This formula gives you the difference of Y over X. In other words, it gives you a tangent line over the 2 points you select. Right? Thats what it does.
 
The derivative of a function is another function that gives the slope of the tangent line to the graph of the first function.
zeromodz said:
Also, whenever you see calculus in advanced physics, I don't understand. You can only use indefinite integrals and derivatives when you have a valid function right? So all these advanced physics problems need functions to go along with them right?
Well of course. In order to differentiate a function or find the antiderivative of one, you need a function to operate on.
 
Mark44 said:
The derivative of a function is another function that gives the slope of the tangent line to the graph of the first function.
Well of course. In order to differentiate a function or find the antiderivative of one, you need a function to operate on.

Okay thank you so much. I understand this a lot better now.
 
zeromodz said:
This formula gives you the difference of Y over X.
Yes. And?
In other words, it gives you a tangent line over the 2 points you select. Right?
No, it does not.

a) First off, what do you call a straight line going through two points on the graph?

b) What, EXACTLY, is the QUANTITY you calculate?
A line is not a "quantity" in this sense!
 
arildno said:
No, it does not.

a) First off, what do you call a straight line going through two points on the graph?

b) What, EXACTLY, is the QUANTITY you calculate?
A line is not a "quantity" in this sense!

a)A secant line! sorry, I just knew that I just put tangent line down for some reason.


b) You are calculating the area under the curve?
 
zeromodz said:
a)A secant line!
Yes it is! :smile:
b) You are calculating the area under the curve?
Is the area under the curve equal to the ratio between the difference of Y-values and X-values??

If not, what geometric interpretation does this ratio have?
 
arildno said:
Yes it is! :smile:

Is the area under the curve equal to the ratio between the difference of Y-values and X-values??

If not, what geometric interpretation does this ratio have?

The ratio of Y over X is tangent. Since the derivative of tangent is sec^2, that is why i get a secant line right? Also, the formula \frac{f(x+h)-f(x)}{h} is what gives you the area under the curve? Sorry I am evading your question with another, just trying to clear things up.
 
  • #10
zeromodz said:
The ratio of Y over X is tangent.
Ok.
Now I get some of your problems.

No, the calculated number will not be "tangent" to the curve here, but it WILL give you the tangent value associated with the angle formed by the secant line and the horizontal line formed at the point (x,f(x)).

You have a natural triangle here in the (x,y)-plane, with corners:
(x,f(x)), (x+h,f(x)) and (x+h,f(x+h))

We usually call that ratio the slope of the line.

Have you heard that expression?
 
  • #11
arildno said:
Ok.
Now I get some of your problems.

No, the calculated number will not be "tangent" to the curve here, but it WILL give you the tangent value associated with the angle formed by the secant line and the horizontal line formed at the point (x,f(x)).

You have a natural triangle here in the (x,y)-plane, with corners:
(x,f(x)), (x+h,f(x)) and (x+h,f(x+h))

We usually call that ratio the slope of the line.

Have you heard that expression?

No, sorry. Its just whenever I thought of Tangent, I thought it was the slope which was rise over run (Y / X). I clearly don't have much understanding here and you're acting more like a teacher rather someone to answer my question which I really appreciate by the way. So its good to think of surrounding the angle with a triangle and then finding out the tangent angle of the triangle?
 
  • #12
No, let us forget about that angle for now. Okay?

1. The most important to remember about that slope, is that it tells you how steep the secant line is between the two points on the graph. Agreed?

2. Now, a tangent line at some point on the graph is that line which a) intersects with graph there, and b) is equally steep as the curve itself there.

3. When you perform the limiting operation (letting h be smaller and smaller) in order to calculate the derivative, you are simply calculating the slopes of successive secant lines and, in the end, when your two points overlap (h=0), sit back with the slope of the tangent line at (x,f(x)), i.e, the slope of the curve itself

4. So, the derivative at some point tells you how steep the curve is at that point.
 
  • #13
arildno said:
No, let us forget about that angle for now. Okay?

1. The most important to remember about that slope, is that it tells you how steep the secant line is between the two points on the graph. Agreed?

2. Now, a tangent line at some point on the graph is that line which a) intersects with graph there, and b) is equally steep as the curve itself there.

3. When you perform the limiting operation (letting h be smaller and smaller) in order to calculate the derivative, you are simply calculating the slopes of successive secant lines and, in the end, when your two points overlap (h=0), sit back with the slope of the tangent line at (x,f(x)), i.e, the slope of the curve itself

4. So, the derivative at some point tells you how steep the curve is at that point.

Okay thank you so much. I am going to take this info and start reading more about it. If I have any questions I will reply to this or PM you. Thank you so much.
 

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