Understanding the Relationship Between Natural Logarithms and Their Reciprocals

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SUMMARY

The relationship between natural logarithms and their reciprocals is defined by the equation 1/loga(e) = loge(a). This identity holds true for all positive real numbers a and the mathematical constant e, approximately equal to 2.718. The proof involves recognizing that if y = loga(e), then e = ay, allowing for substitution and transformation of the logarithmic expressions. Understanding this relationship is crucial for grasping the fundamental properties of logarithms and their applications in mathematics.

PREREQUISITES
  • Understanding of logarithmic functions and their properties
  • Familiarity with the natural logarithm (LN) and its applications
  • Basic knowledge of exponential functions
  • Ability to manipulate algebraic expressions and equations
NEXT STEPS
  • Explore the properties of logarithms, including change of base formulas
  • Study the applications of logarithms in solving exponential equations
  • Learn about the significance of the mathematical constant e in calculus
  • Investigate advanced logarithmic identities and their proofs
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Students studying mathematics, educators teaching logarithmic concepts, and anyone interested in deepening their understanding of logarithmic relationships and their applications in various fields.

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Homework Statement


1/loga(e) = loge(a)

Homework Equations

The Attempt at a Solution


how they are reciprocals of each other ? is their any longer but intuative way to show this result
 
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I think you mean:
\frac{1}{\log_a(e)} = \log_e(a)
 
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phyzguy said:
I think you mean:
\frac{1}{\log_a(e)} = \log_e(a)
yes sir i mean that
 
alijan kk said:
how they are reciprocals of each other ? is their any longer but intuative way to show this result

##a^{\log_a(e)}=e##, right? Just take ##\log_e## of both sides.
 
There's an important part missing from your problem statement:
alijan kk said:

Homework Statement


Prove that[/B] 1/loga(e) = loge(a)
Along the lines of Dick's hint are these relationships:
##y = \log_a(x) \Leftrightarrow x = a^y##
I.e., the two equations are equivalent: any pair of values (x, y) that satisfies the first equation also satisfies the second equation, and vice versa.
 
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Mark44 said:
There's an important part missing from your problem statement:

Along the lines of Dick's hint are these relationships:
##y = \log_a(x) \Leftrightarrow x = a^y##
I.e., the two equations are equivalent: any pair of values (x, y) that satisfies the first equation also satisfies the second equation, and vice versa.
Here is a way that I like to remember it. When I see ##y = \log_a(x) ## and want to convert it to something like ##x = a^y,## I use this to help remember.

Think of log base 10. So we have ##y = \log_{10}(1000) ##. This is pretty easy, there are 3 zeros and the answer is y = 3. The log is equivalent to the exponent.
We have 103 = 1000.
 
scottdave said:
The log is equivalent to the exponent.
Not only that -- a logarithm is by definition an exponent. Specifically, ##\log_a(x)## represents the exponent on a that produces x.
Using your example, ##\log_{10}(1000) = 3## because ##10^3 = 1000##.
 
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I think the relation in the problem statement is true for all positive real a and e. I found this rather difficult to prove. I had to go to a spreadsheet and plug in some values to convince myself it was true. My proof starts with the statement "a=a." Then I substitute an exponential for a on the left hand side. I think I am not supposed to give the full solution here. Good luck! :)
 
Gene Naden said:
I think the relation in the problem statement is true for all positive real a and e.
It wasn't stated in the first post, but the equation is an identity. Yes, it is true for all a > 0, and e is "the natural number," approximately 2.718.

Gene Naden said:
I found this rather difficult to prove.
It's not difficult to prove. Let ##y = \log_a(e)##. This is equivalent to the equation ##e = a^y##. Substitute for e in the expression on the left side of the original equation, ##\frac 1 {log_a(e)}##, and within a couple of steps you end up with the expression on the right side.
 
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  • #10
You can convert a log of one base to another base. I'm on my phone so I'm not sure if I can do LateX correctly though. If you have log(x) in base b. You can calculate it by LN(x) / LN(b), where LN is the natural log (log base e)
 
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  • #11
So using that, substitute LN(e) for 1.
 
  • #12
Oops, I meant loga(a) = 1
 

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