Correct solutions? (1 Viewer)

eternallyboreduser · Jan 26, 2024

Would the following w/o, solutions be considered correct/valid? Thanks in advance

cossine · Jan 27, 2024

eternallyboreduser said:
Would the following w/o, solutions be considered correct/valid? Thanks in advance

View attachment 42248 View attachment 42249 View attachment 42250

15 is good. 19 is too hard to read.

liamkk112 · Jan 27, 2024

eternallyboreduser said:
Would the following w/o, solutions be considered correct/valid? Thanks in advance

View attachment 42248 View attachment 42249 View attachment 42250

for 15 u could give more of a proof as follows:
$y = u_1 u_2 u_3 ... u_n = u_1 (u_2 u_3 ... u_n) \implies y' = (u_1)'(u_2 u_3 ... u_n) + u_1 (u_2 u_3 ... u_n)'$ by the product rule for two functions
then applying the rule again:
$y' = (u_1)' (u_2 u_3 ... u_n) + u_1 (u_2)' (u_3 u _4 ... u_n) + u_1 u_2 (u_3 u_4 ... u_n)'$
then we can see the pattern that you listed above being apparent

eternallyboreduser · Jan 27, 2024

cossine said:
15 is good. 19 is too hard to read.

Wdym by too hard to read? In regards to my handwriting or the way i set out my w/o?

eternallyboreduser · Jan 28, 2024

Bump, anyone mind checking 19b?

Luukas.2 · Jan 28, 2024

19b goes wrong at the end.

You have shown that $PV = a(\alpha - h)^2$ and the distance from $A$ to the axis of symmetry is $D = |\alpha - h|$ . You are required to show that

$PV \propto D^2 \qquad \qquad \text{or equivalently, that} \qquad \qquad \frac{PV}{D^2}\ \text{is constant}$

but you have instead equated them to (erroneously) conclude that $a = 1$ . One possible completion would be:

$\frac{PV}{D^2} = \frac{a(\alpha - h)^2}{|\alpha - h|^2} = \frac{a \times (\alpha - h)^2}{(\alpha - h)^2} = a \qquad \implies \qquad PV \propto D^2\ \quad \text{as $a$ is a constant}$

eternallyboreduser · Jan 28, 2024

Luukas.2 said:
19b goes wrong at the end.

You have shown that $PV = a(\alpha - h)^2$ and the distance from $A$ to the axis of symmetry is $D = |\alpha - h|$ . You are required to show that

$PV \propto D^2 \qquad \qquad \text{or equivalently, that} \qquad \qquad \frac{PV}{D^2}\ \text{is constant}$

but you have instead equated them to (erroneously) conclude that $a = 1$ . One possible completion would be:

$\frac{PV}{D^2} = \frac{a(\alpha - h)^2}{|\alpha - h|^2} = \frac{a \times (\alpha - h)^2}{(\alpha - h)^2} = a \qquad \implies \qquad PV \propto D^2\ \quad \text{as $a$ is a constant}$

Lol i made a ratio thats a : sign not a = sign sorry for the messy handwriting

Luukas.2 · Jan 28, 2024

eternallyboreduser said:
Lol i made a ratio thats a : sign not a = sign sorry for the messy handwriting

Then out equal signs at the LHS of each ratio, showing that the ratio is equal to the line before... or use fractions.

And, the distance to the axis is not $\alpha - h$ , it is $|\alpha - h|$ . You have drawn a diagram is which $\alpha > h$ but nothing in the question requires it, so you need the absolute value for the distance to certainly be positive.

eternallyboreduser · Jan 28, 2024

Luukas.2 said:
Then out equal signs at the LHS of each ratio, showing that the ratio is equal to the line before... or use fractions.

And, the distance to the axis is not $\alpha - h$ , it is $|\alpha - h|$ . You have drawn a diagram is which $\alpha > h$ but nothing in the question requires it, so you need the absolute value for the distance to certainly be positive.

Yeah right forgot to put the abs brackets lol

eternallyboreduser · Jan 28, 2024

eternallyboreduser · Jan 28, 2024

my ngo test in two days please help

eternallyboreduser · Jan 28, 2024

some math god pls tell me if 19b was done right or along the lines of the correct sol

anonymoushehe · Jan 29, 2024

eternallyboreduser said:
some math god pls tell me if 19b was done right or along the lines of the correct sol

this is what the solutions book said

eternallyboreduser · Jan 29, 2024

anonymoushehe said:
View attachment 42268

this is what the solutions book said

Yeah i did not understand what theyre tryna say in that at all hence why i posted it here lo

Luukas.2 · Jan 29, 2024

anonymoushehe said:
View attachment 42268

this is what the solutions book said

The coordinate for the point $T$ is $\left(\alpha,\,a(\alpha - h)^2 + k\right)$ as the solutions posted by @anonymoushehe state.

The coordinate for the point $P$ is $\left(h,\,k - a(\alpha - h)^2\right)$ , matching the solution @eternallyboreduser gave.

The coordinate for the vertex $V$ is $\left(h,\,k\right)$ . Thus, $PV = |a|(\alpha - h)^2$ , noting that we don't actually know if $a$ is positive or negative.

The axis of symmetry runs through the vertex and so is $x = h$ making the perpendicular distance from $A$ to the axis: $d_\perp = |\alpha - h|$ , as we also don't know if $\alpha > h$ or $\alpha < h$ .

As I noted above, @eternallyboreduser has all of this correct except for the missing absolute value signs.

The solutions posted are incorrect in stating that $PV = {d_\perp}^2$ as the latter term is $(\alpha - h)^2$ and not $a(\alpha - h)^2$ (assuming $a > 0$ ), but we can say that:

$\frac{PV}{{d_\perp}^2} = \frac{|a|(\alpha - h)^2}{|\alpha - h|^2} = \frac{|a|(\alpha - h)^2}{(\alpha - h)^2} = |a| \quad \implies \quad PV \propto {d_\perp}^2$

which satisfies the question. Eternallyboreduser, as I stated above, your solution is fine except for the end part.

Luukas.2 · Jan 29, 2024

eternallyboreduser said:
Yeah i did not understand what theyre tryna say in that at all hence why i posted it here lo

Not surprising as the solutions are poorly expressed and contain errors. Issues that I note include:

It is not clear that the "coordinate for the tangent" refers to the point $T$ where the tangent touches the curve and not the point $P$ that we seek, where the tangent meets the axis.
The coordinates $(h,\,k)$ represent the vertex and not the axis of symmetry - which is a line, and so can't be represented by a single point - though this point is where the axis of symmetry crosses the curve.
The point $A$ lies on the $x$ -axis vertically above / below the point $T$ and is in no sense representative of the vertex.
However, as the axis of symmetry is vertical, the perpendicular distance from it to $A$ is horizontal, and so the required distance is from the point $A$ to $(h,\,0)$ . The answers do not state this value, though it is $|\alpha - h|$ .
Both $P$ and $V$ lie on the axis and so this distance is vertical (and so the $k$ coordinates will cancel in the distance formula, which is what the answers are trying to state), yielding $PV = |a|(\alpha - h)^2$ , as you showed (apart from the absolute value).
The final statement that the distances are the same is simply wrong. Having not stated the distance from the axis of symmetry, this would certainly be penalised because it implies that the perpendicular distance is $\sqrt{a}(\alpha - h)$ , which it isn't... and the perpendicular distance squared is not a distance anyway...

Though not actually an error, the lack of a diagram is poor practice when answering a question like this.

Correct solutions? (1 Viewer)

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