PG1995
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The difference between the top formulas and the corresponding bottom formulas is that the bottom formulas are more general and include a scale factor "a" in the function. So if a=1, you get the top formulas, and if "a" not equal to 1 then you need the more general formulas.
Thank you, Steve, MrAl.
What do you mean by "scale factor"? Do you mean to say that the function f(x) being multiplied by "a" as in e^{a*f(x)}.
I was playing around with my calculator where I entered this expression just randomly. Is there any simple way to evaluate it? It seems it's difficult to integrate because my calculator only simplifies it to: [latex]$7.39\int e^{2x^{2}}dx$[/latex], and a software package also fails to simplify it. Please help me with it. Thank you.
Regards
PG
I was playing around with my calculator where I entered this expression just randomly. Is there any simple way to evaluate it?
steveB said:A scale factor is just a constant that multiplies a variable. In this case the letter "a" is clearly shown in your formulas 14.339 and 14.509. So, there should be no confusion about what I mean by saying that these formulas include a scale factor "a". If you set a=1, the you get formulas 14.9 and 14.11. It's as simple as that.
Obviously I was wrong. Besides, the expression "(x^2+1)" isn't a variable, it's a function in itself.
Hi
Could you please help me with this **broken link removed**? Thanks a lot.
Regards
PG
MrAl said:Actually a piecewise continuous function can NOT have sudden jumps in it, it can only have sudden turns.
So that's why they wanted to say piecewise continuous, so the function requirement is less constrictive.
A piecewise function can have both sudden jumps and sudden turns.
So a piecewise function and a piecewise continuous function are two different animals.
Thank you, Steve, MrAl.
The quoted section above is the gist of it. In my view, continuous functions are a subset of a piecewise continuous functions and that's the reason the book used the terminology it did.
Regards
PG
I have to disagree with the above. A piecewise continuous function is usually defined to be that which is continuous within a finite number of regions, and then finite discontinuities are allowed at the boundaries between pieces.
I expect the reference cited by PG is using this definition, but I guess PG needs to verify by reading the reference.
https://www.electro-tech-online.com/custompdfs/2012/10/pg13.pdf
If you think about it, there is no issue integrating through a finite number of discontinuities. One simply breaks the full integral into a finite number of integrals over each continuous piece.