A particle shows distance-time curve as given in this figure. The maximum instantaneous velocity of the particle is around the point

Maths-

The area bounded by $y equals x squared plus 2 comma$ X- axis, x=1 and x=2 is

So now here we can say that using the integration method, the area of the region bounded by the given curve and the lines is 13/3. The equation A = ∫ab f(x) dx gives the area under the curve y = f(x) and x-axis. The bounding values for the curve with respect to the x-axis are shown here as a and b.

The area bounded by $y equals x squared plus 2 comma$ X- axis, x=1 and x=2 is

Maths-General

If $Cos space 2 theta times Cos space 3 theta times cos space theta equals 1 fourth text for end text 0 less than theta less than pi$ then $theta$ =

The $x minus t$ graph shown in the figure represents

For the velocity-time graph shown in figure below the distance covered by the body in last two seconds of its motion is what fraction of the total distance covered by it in all the seven seconds

A particle starts from rest at $t equals 0$ and undergoes an acceleration $a$ in $m s to the power of negative 2 end exponent$ with time $t$ in second which is as shownWhich one of the following plot represents velocity $v$ in $m s to the power of negative 1 end exponent blank v e r s u s$ time $t$ in second?

A body is at rest at $x equals 0$ . At $t equals 0$ , it starts moving in the positive $x$ -direction with a constant acceleration. At the same instant another body passes through $x equals 0$ moving in the positive $x$ -direction with a constant speed. The position of the first body is given by $x subscript 1 end subscript left parenthesis t right parenthesis$ after time ‘ $t$ ’ and that of the second body by $x subscript 2 end subscript left parenthesis t right parenthesis$ after the same time interval. Which of the following graphs correctly describes $left parenthesis x subscript 1 end subscript minus x subscript 2 end subscript right parenthesis$ as a function of time ‘ $t$ ’

General solution of $2 to the power of x equals n x end exponent plus 2 to the power of cos space x end exponent equals 2 to the power of 1 minus fraction numerator 1 over denominator square root of 2 end fraction end exponent$ is

In the following graph, distance travelled by the body in metres is

Velocity-time $open parentheses v minus t close parentheses$ graph for a moving object is shown in the figure. Total displacement of the object during the time interval when there is non-zero acceleration and retardation is

Maths-

The value of k such that $fraction numerator x minus 4 over denominator 1 end fraction equals fraction numerator y minus 2 over denominator 1 end fraction equals fraction numerator z minus k over denominator 2 end fraction$ lies in the plane 2x-4y+z+7=0 is

So here we used the concept of three dimensional geometry to understand and solve the question. Any point's position or coordinates in 3D space are determined by how far they have travelled along the x, y, and z axes, respectively. So here the value of k is 7.

The value of k such that $fraction numerator x minus 4 over denominator 1 end fraction equals fraction numerator y minus 2 over denominator 1 end fraction equals fraction numerator z minus k over denominator 2 end fraction$ lies in the plane 2x-4y+z+7=0 is

Maths-General

The distance between the line $fraction numerator x minus 2 over denominator 1 end fraction equals fraction numerator y plus 2 over denominator negative 1 end fraction equals fraction numerator z minus 3 over denominator 4 end fraction$ and the plane $stack r with ‾ on top times left parenthesis stack i with ‾ on top plus 5 stack j with ‾ on top plus stack k with ‾ on top right parenthesis equals 5$ is (units)

The number of solutions of the equation $Sin space 3 alpha equals 4 Sin space alpha times Sin space left parenthesis x plus alpha right parenthesis times Sin space left parenthesis x minus alpha right parenthesis$ where $0 less than alpha less than pi$ for $straight x$ in the interval $left square bracket 0 comma pi right square bracket$ is

The displacement-time graph of a moving object is shown in figure. Which of the velocity-time graphs shown in figure could represent the motion of the same body?

The value of k for which the lines $fraction numerator x plus 1 over denominator negative 3 end fraction equals fraction numerator y plus 5 over denominator 2 k end fraction equals fraction numerator z minus 4 over denominator 2 end fraction$ and $fraction numerator x minus 3 over denominator 3 k end fraction equals fraction numerator y minus 2 over denominator 1 end fraction equals fraction numerator z plus 1 over denominator 7 end fraction$ are perpendicular is