A quadratic function f(x) attains a max of 3 at x =1, the

Nice explanation sriharimurthy.

I did some calculation mistake,
answer is A, -159.

My approach:

\(f(x)=ax^2+bx+c\)

Given for\(x=0\), \(f(x)=1\)
so \(c=1\)
Given for \(x=1\), \(f(x)=3\)
so \(a+b+c=3\)
\(a+b=2\)

now question is \(100a+10b+c=?\)
\(90a+10(a+b)+c\)
\(90a+21=?\)

a, b, and c are integers

now pick an answer choice for which a is an integer

\(90a+21=-159\)
\(a=-2\)

so A is the answer.

wow!!
grt job
i solved lke this and got -159 ,but was not sure abt the ans

let f(x) = ax2 + bx +c

at x = 0 value of f(x) = 1 so equation becomes

1 = c

since it attains max of 3 at x =1

3 = a+b+c put c=1

a+b = 2

now differntiate f(x) we will get 2ax +b =0 since it attains max at x =1 relaion becomes 2a = -b

now u will get values of a=-2,b =4 nd c =1

f(x) = -2x2 + 4x + 1

now put x = 10 nd answer is -159

Not sure this would be on the GMAT, seems you should use calculus for this.

ax^2+bx+c=0

f(1)=3=a+b+c
f(0)=1=c

f'(x)= 2xa+b.

since the max is 3, f'(1)=0. Thus, 0=2a+b--> b=-2a --> 2=a-2a --> -2=a

f(10) = -2*100+10(4)+1 --> -159

You've got 3 points and 3 equations, so you could use a system of equations to solve.
Coordinates: (1,3) Given, (0,1) Given, and (2,1) Implied. I got (2,1) by doing a really rough sketch and seeing that (2,1) is a mirror of (0,1) with (1,3) as the max.

3 systems in quadratic form:
a(1)^2 + b(1) + c = 3
a(0)^2 + b(0) + c = 1
a(2)^2 + b(2) + c = 1

a + b + c = 3
c = 1
4a + 2b + c = 1

Solving this would yield a = -2, b = 4, c = 1.
f(x) = -2x^2 + 4x + 1

Then, just plug in 10 for x and solve.

Hey guys,

I understand how you arrived at the f(x)=ax^2+bx+c, but you I don't fully understand how you arrived at 2x^2+4x+1. Could you please explain a little more?

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We have the function \(f(x)=ax^2+bx+c\).

Stem: the value of the function at x =0 is 1.

Substitute x by 0 --> \(f(0)=1=a*0^2+b*0+c\) --> \(c=1\), hence the function becomes: \(f(x)=ax^2+bx+1\).


Stem: A quadratic function f(x) attains a max of 3 at x =1.

\(f_{max}(1)=3=ax^2+bx+1=a*1^2+b*1+1=a+b+1\), --> \(a+b+1=3\) --> \(a+b=2\).

Also the property of quadratic function:

The maximum (or minimum if a>0) of the quadratic function \(f(x)=ax^2+bx+c\) is the y coordinate (the value of f(x)) of the vertex of the given quadratic function, which is parabola.

The vertex of the parabola is located at the point \((-\frac{b}{2a},\) \(c-\frac{b^2}{4a})\).

Given: A quadratic function f(x) attains a max of 3 at x =1 --> coordinates of the vertex are (1, 3) --> \(-\frac{b}{2a}=1\), \(c-\frac{b^2}{4a}=3\)

So we have:
\(a+b=2\)
and:
\(-\frac{b}{2a}=1\)

From this \(a=-2\) and \(b=4\). so the function is: \(f(x)=-2x^2+4x+1\)

Hope it's clear.

I was not aware about the concept of maximum value of quadratic equation is (\(\frac{-b}{2a}, c-\frac{b^2}{4a}\)). This goes in my notebook.

However, I used POE technique.

f(x) = \(ax^2 +bx+c\)

x=1, a+b+c =3
x=0, c=1
Hence, a+b = 2 or b = 2-a

So, f(10) = 100a+10b+c = 100a + 10(2-a) +c = 90a + 21 = 3(30a + 7)

So, we understand the value is a multiple of 3. Hence, shortlisting a)-159, c)-180, d)-105

Now, 90a+21. the last digit can end up in 1 if a is =+ve or 9 if a is -ve

Only option with last digit 9 is a) -159

Hence A.

Here, the function takes the max value of 3 at x = 1. So it is a downward open parabola.

Say it is \(f(x) = ax^2 + bx + c\)
Since its value is 1 at x = 0, we get c = 1.

Also at x = 1, \(a + b + 1 = 3\)
So a + b = 2

Since the graph takes the max value at x = 1, we know that -b/2a = 1. So b = -2a.
Using this in the equation above, we get a = -2 and b = 4

So f(x) becomes \(-2x^2 + 4x + 1\).

When x = 10, we get -159.

Answer (A)

I used this form:

y = +- a(x-k)^2 + c

Since the question specifically indicates that a maximum value is present, then the parabola should be facing downwards (a should be negative)

y = -a(x-k)^2 + c

Knowing that the function is maximum at x = 1, therefore, k = 1. We can see here that whatever happens, the term (x-k)^2 is greater than or equal to zero. In order to maximize, we must make sure that this part of the expression will be minimum; hence, equal to 0.

we now know that k = 1, and c = 3.

y = -a(x-1)^2 + 3

To get the value of a, use the second constraint. At x = 0, a should be equal to 2 so that y = 1.

y = -2(x-1)^2 + 3

Substitute x = 10 to get the answer.

Answer is -159.

When a quadratic function opens downward, the apex or vertex is the maximum value of f(x) that can be achieved.

The quadratic function for a downward opening parabola should take the form:

F(X) = a(X)^2 + b(X) + c

Where the value of the a coefficient will be Negative

The maximum value or vertex will occur at the vertical line given by the X -Coordinate of:

X = -b / (2a)

Since we are told that this maximum occurs at f(x) = 3 when X = 1

1 = -b / (2a)

2a = -b

b = -2a


Additionally, we are told that we X = 0, the Y -Intercept will be 1 ————> c = 1


Plugging in:
b = -2a
c = 1

f(x) = a(X)^2 - 2a(X) + 1

Finally, we can plug in the coordinate of (1 , 3) to find the value of a

3 = a(1)^2 - 2a(1) + 1

2 = a - 2a

2 = -a

Or

a = -2

And

b = +4

The function will take the form:

F(X) = -2(X)^2 + 4(X) + 1

Plugging in the X coordinate of 10, we get:

F(10) = -200 + 40 + 1

Answer

-159

(A)

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This solution is easier using co-ordinate geometry, rather than differencian formula f(max)=-b/2a

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