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APPLICATION OF DERIVATIVES — Maths STD 12 Science — Question

Gujarat BoardEnglish MediumSTD 12 ScienceMathsAPPLICATION OF DERIVATIVES4 Marks
Question
Shobhit's father wants to construct a rectangular garden using a brick wall on one side of the garden and wire fencing for the other three sides as shown in figure. He has 200 ft of wire fencing.

Based on the above information, answer the following questions.
  1. To construct a garden using 200 ft of fencing, we need to maximise its.
  1. Volume
  2. Area
  3. Perimeter
  4. Length of the side
  1. If x denote the length of side of garden perpendicular to brick wall and y denote the length of side parallel to brick wall, then find the relation representing total amount of fencing wire.
  1. $x + 2y = 150$
  2. $x + 2y = 50$
  3. $y + 2x = 200$
  4. $y + 2x = 100$
  1. Area of the garden as a function of x, say A(x), can be represented as.
  1. $200 + 2x^2$
  2. $x - 2x^2$
  3. $200x - 2x^2$
  4. $200 - x^2$
  1. Maximum value of A(x) occurs at x equals.
  1. 50 ft
  2. 30 ft
  3. 26 ft
  4. 31 ft
  1. Maxi mum area of garden will be.
  1. 2500 sq. ft
  2. 4000 sq. ft
  3. 5000 sq. ft
  4. 6000 sq. ft

Answer

  1. (b) Area
Solution:
To create a garden using 200 ft fencing, we need to maximise its area.
  1. (c) y + 2x = 200
Solution:
Required relation is given by 2x + y = 200.
  1. (c) $200x - 2x^2$
Solution:
Area of garden as a function of x can be rep resented as
$A(x) = x·y = x(200 - 2x) = 200x - 2x^2$
  1. (a) 50 ft
Solution:
$A(x) = 200x - 2x^2 \Rightarrow A'(x) = 200 - 4x$
For the area to be maximum $A'(x) = 0$
$\Rightarrow 200 - 4x =0$
$\Rightarrow x = 50 ft​​​​​​​$
  1. (c) 5000 sq. ft
Solution:
Maximum area of the garden = $200(50) - 2(50)^2 = 10000 - 5000 = 5000$ sq. ft

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On her birthday, Seema decided to donate some money to the children of an orphanage home. If there were $8$ children less, everyone would have got $₹10$ more. However, if there were $16$ children more, everyone would have got $₹10$ less. Let the number of children be $\mathrm{x}$ and the amount distributed by Seema for one child be $\mathrm{y} \ ($in $₹)$.Image
$(i)$ Represent given information in matrix algebra.
$(ii)$ Find the adjoint of Matrix containing information about of number of children and amount she paid?
$(iii)$ Find the number of children who were given some money by Seema?
OR
How much amount does Seema spend in distributing the money to all the students of the Orphanage?
Megha wants to prepare a handmade gift box for her friend's birthday at home. For making lower part of box, she takes a square piece of cardboard of side $20$cm.

Based on the above information, answer the following questions.
  1. If $x$ cm be the length of each side of the square cardboard which is to be cut off from corners of the square piece of side 20cm, then possible value of $x$ will be given by the interval.
  1. $[0, 20]$
  2. $(0, 10)$
  3. $(0, 3)$
  4. None of these
  1. Volume of the open box formed by folding up the cutting corner can be expressed as.
  1. $\text{V}=\text{x}(20-2\text{x})(20-2\text{x)}$
  2. $\text{V}=\frac{\text{x}}{2}(20+\text{x})(20-\text{x})$
  3. $\text{V}=\frac{\text{x}}{3}(20-\text{x})(20+\text{x})$
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  1. Megha is interested in maximizing the volume of the box. So, what should be the side of the square to be cut off so that the volume of the box is maximum?
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  3. $\frac{10}{3}\text{cm}$
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  1. $\frac{17000}{27}\text{cm}^3$
  2. $\frac{11000}{27}\text{cm}^3$
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A plane started from airport situated at O with a velocity of 120m/s towards east. Air is blowing at a velocity of 50m/ s towards the north as shown in the figure.
The plane travelled 1hr in OP direction with the resultant velocity. From P to R the plane travelled 1hr keeping velocity of 120m/s and finally landed at R.

Based on the above information, answer the following questions.
  1. What is the resultant velocity from O to P?
  1. 100m/ s
  2. 130m/ s
  3. 126m/ s
  4. 180m/ s
  1. What is the direction of travel of plane from O to P with East?
  1. $\tan^{-1}\Big(\frac{5}{12}\Big)$
  2. $\tan^{-1}\Big(\frac{12}{3}\Big)$
  3. 50
  4. 80
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  1. 600km
  2. 468km
  3. 532km
  4. 500km
  1. What is the resultant velocity from P to R?
  1. 120m/ s
  2. 70m/ s
  3. 170m/ s
  4. 200m/ s
  1. What is the displacement from P to R?
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  3. 610km
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A thermometer reading 80°F is taken outside. Five minutes later the thermometer reads 60°F. After another 5 minutes the thermometer reads 50°F. At any time t the thermometer reading be T°F and the outside temperature be S°F.

Based on the above information, answer the following questions.
  1. If $\lambda$ is posinve constant of propornonality, then $\frac{\text{dn}}{\text{dt}}$ is:
  1. $\lambda(\text{T - S})$
  2. $\lambda(\text{T + S})$
  3. $\lambda\text{T S}$
  4. $-\lambda(\text{T - S})$
  1. The value of T(S) is:
  1. 30°F
  2. 40°F
  3. 5D°F
  4. 60°F
  1. The value of T(10) is:
  1. 50°F
  2. 60°F
  3. 80°F
  4. 90°F
  1. Find the general solution of differential equation fanned in given situation.
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  2. $\log(\text{T}-\text{S})=\lambda{\text{t + c}}$
  3. $\log\text{T}=\text{tT + c}$
  4. $\log(\text{T + S})=\lambda{\text{t + c}}$
  1. Find the value of constant of integration c in the solution of differential equation formed in given situation.
  1. $\log(60\ -\ \text{S})$
  2. $\log(80\ +\ \text{S})$
  3. $\log(80\ -\ \text{S})$
  4. $\log(60\ +\ \text{S})$
A company produces three products every day. Their production on certain day is $45$ tons. It is found that the production of third product exceeds the production of first product by $8$ tons while the total production of first and third product is twice the production of second product.

Using the concepts of matrices and determinants, answer the following questions.
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  1. $x + y + z = 45$
  2. $x + 8 = z$
  3. $x - 2y + z = 0$
  4. All of these.
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  3. $\begin{pmatrix}\frac{1}{3}&\frac{1}{2}&\frac{1}{6}\\\frac{1}{3}&0&\frac{-1}{3}\\\frac{1}{3}&\frac{-1}{2}&\frac{1}{6}\end{pmatrix}$
  4. None of these.
  1. $x : y : z$ is equal to:
  1. $12 : 13 : 20$
  2. $11 : 15 : 19$
  3. $15 : 19 : 11$
  4. $13 : 12 : 20$
  1. Which of the following is not true?
  1. $|A| = |A'|$
  2. $(A')^{-1} = (A^{-1})'$
  3. $A$ is skew synunetric matrix of odd order, then $|A| = 0$
  4. $|AB| = |A| + |B|$
  1. Which of the following is not true in the given determinant of $A,$ where A $=[\text{a}_\text{ij}]_{3\times3}?$
  1. Order of minor is less than order of the det $(A).$
  2. Minor of an element can never be equal to cofactor of the same element.
  3. Value of a determinant is obtained by multiplying elements of a row or column by corresponding cofactors.
  4. Order of minors and cofactors of same elements of $A$ is same.
Two schools $A$ and $B$ want to award their selected students on the values of Honesty, Hard work and Punctuality. The school $A$ wants to award $₹ x$ each, $₹ y$ each and $₹ z$ each for the three respective values to its $3, 2$ and $1$ students respectively with a total award money of $₹ 2200$. School $B$ wants to spend $₹ 3100$ to award its $4, 1$ and $3$ students on the respective values $($by giving the same award money to the three values as school $A)$. The total amount of award for one prize on each value is $₹ 1200.$

Using the concept of matrices and determinants, answer the following questions.
  1. What is the award money for Honesty?
  1. $₹ 350$
  2. $₹ 300$
  3. $₹ 500$
  4. $₹ 400$
  1. What is the award money for Punctuality?
  1. $₹ 300$
  2. $₹ 280$
  3. $₹ 450$
  4. $₹ 500$
  1. What is the award money for Hard work?
  1. $₹ 500$
  2. $₹ 400$
  3. $₹ 300$
  4. $₹ 550$
  1. If a matrix $P$ is both symmetric and skew-symmetric, then |P| is equal to:
  1. $1$
  2. $-1$
  3. $0$
  4. None of these.
  1. If $P$ and $Q$ are two matrices such that $PQ = Q$ and $QP = P,$ then $|Q^2|$ is equal to:
  1. $|Q|$
  2. $|P|$
  3. $1$
  4. $0$
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Based on the above information, answer the following questions.
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  1. $\tan^{-1}\frac{\text{x}}{\text{y}}=\log|\text{x}|+\text{c}$
  2. $\tan^{-1}\frac{\text{y}}{\text{x}}=\log|\text{x}|+\text{c}$
  3. $\text{y}=\text{x}\log|\text{x}|+\text{c}$
  4. $\text{x}=\text{y}\log|\text{y}|+\text{c}$
  1. Solution of the differential equation $2\text{xy}\frac{\text{dy}}{\text{dx}}=\text{x}^2+3\text{y}^2$ is:
  1. $x^3 + y^2 = cx^2$
  2. $\frac{\text{x}^2}{2}+\frac{\text{y}^3}{3}=\text{y}^2+\text{c}$
  3. $x^2 + y^3 = cx^2$
  4. $x^2 + y^2 = cx^3$
  1. General solution of the differential equation ($x^2 + 3xy + y^2) dx - x^2 dy = 0$ is:
  1. $\frac{\text{x+y}}{\text{y}}-\log\text{x = c}$
  2. $\frac{\text{x+y}}{\text{y}}+\log\text{x = c}$
  3. $\frac{\text{x}}{\text{x+y}}-\log\text{x = c}$
  4. $\frac{\text{x}}{\text{x+y}}+\log\text{x = c}$
  1. General solution of the differential equation $\frac{\text{dy}}{\text{dx}}=\frac{\text{y}}{\text{x}}\bigg\{\log\Big(\frac{\text{y}}{\text{x}}\Big)+1\bigg\}$ is:
  1. $\log(\text{xy})=\text{c}$
  2. $\log\text{y}=\text{cx}$
  3. $\log\frac{\text{y}}{\text{x}}=\text{cx}$
  4. $\log\text{x}=\text{cy}$
  1. Solution of the differential equation $\Big(\text{x}\frac{\text{dy}}{\text{dx}}-\text{y}\Big)\text{e}^\frac{\text{y}}{\text{x}}=\text{x}^2\ \cos\text{x}$ is:
  1. $\text{e}^\frac{\text{y}}{\text{x}}-\sin\text{x = c}$
  2. $\text{e}^\frac{\text{y}}{\text{x}}+\sin\text{x = c}$
  3. $\text{e}^\frac{\text{-y}}{\text{x}}-\sin\text{x = c}$
  4. $\text{e}^\frac{\text{-y}}{\text{x}}+\sin\text{x = c}$
Read the following text carefully and answer the questions that follow:
Once Ramesh was going to his native place at a village near Agra. From Delhi and Agra he went by flight, In the way, there was a river. Ramesh reached the river by taxi. Then Ramesh used a boat for crossing the river. The boat heads directly across the river $40 m$ wide at $4 m/s$. The current was flowing downstream at $3 m/s.$
Image
$i.$ What is the resultant velocity of the boat? $(1)$
$ii$. How much time does it take the boat to cross the river? $(1)$
$iii$. How far downstream is the boat when it reaches the other side? $(2)$​​​​​​​
OR
If speeds of boat and current were $1.5 m/s$ and $2.0 m/s$ then what will be resultant velocity? $(2)$
Geetika's house is situated at Shalimar Bagh at point O, for going to Alok's house she first travels 8km by bus in the East. Here at point A, a hospital is situated. From Hospital, Geetika takes an auto and goes 6km in the North, here at point B school is situated. From school, she travels by bus to reach Alok's house which is at 30º East, 6km from point B.

Based on the above information, answer the following questions.
  1. What is the vector distance between Geetika's house and school?
  1. $8\hat{\text{i}}-6\hat{\text{j}}$
  2. $8\hat{\text{i}}+6\hat{\text{j}}$
  3. $8\hat{\text{i}}$
  4. $6\hat{\text{j}}$
  1. How much distance Geetika travels to reach school?
  1. 14km
  2. 15km
  3. 16km
  4. 17km
  1. What is the vector distance from school to Alok's house?
  1. $\sqrt{3}\hat{\text{i}}+\hat{\text{j}}$
  2. $3\sqrt{3}\hat{\text{i}}+3\hat{\text{j}}$
  3. $6\hat{\text{i}}$
  4. $6\hat{\text{j}}$
  1. What is the vector distance from Geetika's house to Alok's house?
  1. $(8+3\sqrt{3})\hat{\text{i}}+9\hat{\text{j}}$
  2. $4\hat{\text{i}}+6\hat{\text{j}}$
  3. $15\hat{\text{i}}$
  4. $16\hat{\text{j}}$
  1. What is the total distance travelled by Geetika from her house to Alok's house?
  1. 19km
  2. 20km
  3. 21km
  4. 22km
Two multi-storey buildings $($represented by $AP$ and $BQ)$ are on opposite side of a 20m wide road at point $A$ and $B$ respectively. There is a point $R$ on road as shown in figure.

Based on the above information, answer the following questions.
  1. Area of trapezium $ABQP$ is.
  1. $380$ sq. m
  2. $280$ sq. m
  3. $320$ sq. m
  4. $430$ sq. m
  1. The length PQ is.
  1. $20.5$m
  2. $19.80$ m
  3. $20.88$m
  4. $21$m
  1. Let there be a quantity $S$ such that $S = RP^2 + RQ^2$, then $S$ is given by.
  1. $2x^2 - 40x - 1140$
  2. $2x^2 + 40x + 1140$
  3. $2x^2 - 40x + 1140$
  4. $2x^2 + 40x - 1140$
  1. Find the value of $x$ for which value of $S$ is minimum.
  1. $10$
  2. $0$
  3. $4$
  4. $-10$
  1. For minimum value of $S,$ find the value of $PR$ and $RQ.$
  1. $18.50$m, $19.36$m
  2. $18.86$m, $24.17$m
  3. $17.56$m, $23.29$m
  4. None of these