Office_Shredder said:For the second one then, try writing it as sin(1/x)/(1/x), then do the substitution v=1/x.
Note that when you do a substitution like this, it's not completely rigorous as 1/x can go to +/- infinity as v goes to zero, and similar problems going in reverse, but it gives a very strong intuitive feel for what's going on, and with care can be made rigorous
thrive said:The crux of the whole problem is that I don't know how to handle Sin(undefined)
edit: answer is DNE, I am stupid :< as sin function approaches 0, there is no value that it locks onto...it just keeps oscillating up and down like the sin function does, infinitely.
kuahji said:If all else fails, use numerical methods to find the limit.
wow I am completely lost with that explanation. All i got was that sin(0)/0 would occur...aka indeterminate form
thrive said:2. lim xsin(1/x) i believe the answer is infinity
x>00
3. lim (tan(5x)/sec(5x))*((cos(3x)/4x))
x>0
dynamicsolo said:In following OfficeShredder's suggestion, you got lim u->0 [sin(u)/u]. You are correct is that the Limit Laws would give an indeterminate form. However, there is a proof concerning this particular limit; have you had that in your book or course?
You will need the result for lim u->0 [sin(u)/u] in order to do this one. To make your work somewhat easier, rewrite this in terms of just sine and cosine functions. You will have one place where you need the (sin u)/u limit , given that u can be a function of x, but you will have to make an adjustment by multiplication and division of constants.
i just do not understand how the lim x->0 of [xsin(1/x)] relates to this
Office_Shredder said:...then xsin(1/x)=sin(1/x)/(1/x)=sin(v)/v where v is going to zero.
Dick said:If x->infinity, v=1/x->0.
Limit problems are mathematical exercises that involve finding the behavior of a function as the input approaches a certain value. They are important because they help us understand the properties of functions and their behavior near certain points.
To solve a basic limit problem, you need to evaluate the function at the given value and see what number it approaches as the input gets closer and closer to that value. This is known as taking the limit of the function.
Some common techniques for solving limit problems include algebraic manipulation, factoring, using trigonometric identities, and applying special limit rules such as the squeeze theorem or L'Hôpital's rule.
Yes, there are some limit problems that cannot be solved using algebraic techniques. For example, some functions may have limits that approach infinity or oscillate infinitely, making it difficult to find a precise solution.
Limit problems are commonly used in physics, engineering, and other fields to model and understand real-life situations. For example, they can be used to analyze the behavior of a system as it approaches a critical point or to predict the rate of change of a process.