Hmm you're probably right but seeing as both are f(x) then it shouldn't matter which one you use if they equal the same thing? As both should give the same y intercept? Unless they wanted us to find g(x) or something which has the same roots as f(x) but a different intercept?
Uhm its effectively the same graph yes, because it has the same roots. But if you think of it in terms of transformations in C2, the original factorised form is f(x).
What we've then factorised it into is 2(fx) i.e. a stretch s.f. 2 parallel to the y-axis (basically a vertical stretch scale factor 2). This means where it crosses the x-axis will remain the same (only a vertical stretch) but where it crosses the y-axis, that value will double.
I don't really know if I've explained this clearly, but that's my interpretation of the difference..
Uhm its effectively the same graph yes, because it has the same roots. But if you think of it in terms of transformations in C2, the original factorised form is f(x).
What we've then factorised it into is 2(fx) i.e. a stretch s.f. 2 parallel to the y-axis (basically a vertical stretch scale factor 2). This means where it crosses the x-axis will remain the same (only a vertical stretch) but where it crosses the y-axis, that value will double.
I don't really know if I've explained this clearly, but that's my interpretation of the difference..
Ahh that makes sense, I thought they wanted me to find another form of f(x) that happened to have a coefficient of 2. Dammit you'd think 3rd time lucky I'd nail that paper I must admit I wasn't sure so on the last two parts of 11 I wrote the alternative and put a neat line through it, just in case they want to give me the benefit of the doubt...
I'm sure you'll do well its only 1 question, and C1s kinda tricky. I think this paper was quite a hard one imo (in comparison), so I'm sure you'll be ok
Judging on previous papers my geuss would be 63 Max and 58 Min but personally im thinking around 61. Of course it is hard to tell
i doubt it'll be that high ...i did an really easy paper a few days ago and it was 58 for an A.. for A im guesing 57-58 tbh :/ havent seen a paper wiv 60 for an A o.o i found this was a medium difficulty paper :P last year's june 11 was 55
i doubt it'll be that high ...i did an really easy paper a few days ago and it was 58 for an A.. for A im guesing 57-58 tbh :/ havent seen a paper wiv 60 for an A o.o i found this was a medium difficulty paper :P last year's june 11 was 55
Yes i see, but i found this paper really easy. I guess it is hard too tell. there has been a 60 and a few 58s. i would love it to be 55, fingers crossed!
Yes i see, but i found this paper really easy. I guess it is hard too tell. there has been a 60 and a few 58s. i would love it to be 55, fingers crossed!
I looked through all grade boundaries from 08 to jan 12. The lowest was 52 for an A and highest 62 for an A. I think it will be around 59 like Jan
Shouldn't it be two separate equalities: K > Sqrt5 and K<-Sqrt5
I dont think so, i believe the question was for when there was no intersection which would mean -SQRT(5) < K < SQRT(5) although if you mean shoud it just be written as 2 equalities then i believe it does not matter.
I dont think so, i believe the question was for when there was no intersection which would mean -SQRT(5) < K < SQRT(5) although if you mean shoud it just be written as 2 equalities then i believe it does not matter.
I'm pretty sure if K was a value between -sqrt5 and sqrt5 then it would intercept the axis, however if K was either bigger then sqrt5 or smaller then -sqrt5 then there will be no roots.
I'm pretty sure if K was a value between -sqrt5 and sqrt5 then it would intercept the axis, however if K was either bigger then sqrt5 or smaller then -sqrt5 then there will be no roots.
It is b^2 - 4ac and you ended up with like 4k^2-20<0 so K needs to be as small as possible and if k is bigger than SQRT(5) for example 10 then if you sub that back in you end up with 400-20 = 380 which you can square root and therefore find an intercept.
I will double check my working tomoro and hopefully revise the answers!
I have an issue with your question 11, if you take the original factorised form of (x+1/2)(x+2)(x-5) then the y intercept would be -5 not -10. I put the equations 2x^3 -5x^2 -23x -10 and the expanded form of the factorised equation into autograph and they aren't the same. So to get from the factorised equation to one with a coefficient of 2, you can't just double everything or I believe you get a false y intercept (but no idea how you actually get there).
So if I'm correct, the answer for the y intercept of f(x) -8 is (0, -13) and the answer to f(x-3) is -20?
Sorry if someone has already pointed this out
To get it in the form of 2x^3 + bx^2 + cx + d as required by the question, you need to have one of your factors as (2x + h) where h is a constant. (x + .5) => (2x + 1)
Otherwise you don't get 2x^3, you only get x^3 which wasn't asked for in the question.
I'm pretty sure if K was a value between -sqrt5 and sqrt5 then it would intercept the axis, however if K was either bigger then sqrt5 or smaller then -sqrt5 then there will be no roots.
The original equation was x^2+2kx+5 and the answer was -sqrt5<k<sqrt5, *because if you take 3 as a value of k, for example, which is bigger than sqrt5, the discriminant of the equation becomes to be bigger than 0 which means that there are 2 real roots. also if you take -3 as a value of k, which is smaller than -sqrt5, the discriminant also gives a value greater than 0. The question asks for range of values of k where the equation doesn't intersect the x-axis therefore it has to be -sqrt5<k<sqrt5 and you can try any values in between and the discriminant will always be less than 0.*
Take k=1,
Therefore, b^2-4ac: =2^2-(4*1*5) =4-20 =-16 The discriminant is less than 0, so no real roots so no intersections with the x-axis.
Yes i see, but i found this paper really easy. I guess it is hard too tell. there has been a 60 and a few 58s. i would love it to be 55, fingers crossed!
The original equation was x^2+2kx+5 and the answer was -sqrt5<k<sqrt5, *because if you take 3 as a value of k, for example, which is bigger than sqrt5, the discriminant of the equation becomes to be bigger than 0 which means that there are 2 real roots. also if you take -3 as a value of k, which is smaller than -sqrt5, the discriminant also gives a value greater than 0. The question asks for range of values of k where the equation doesn't intersect the x-axis therefore it has to be -sqrt5<k<sqrt5 and you can try any values in between and the discriminant will always be less than 0.*
Take k=1,
Therefore, b^2-4ac: =2^2-(4*1*5) =4-20 =-16 The discriminant is less than 0, so no real roots so no intersections with the x-axis.