Competitive Math Made Easy

Key Facts If a person can finish a job in n days, then the work done by the person in 1 day is $\frac{1}{n}$th of the total job If a person completes $\frac{1}{n}$th of the total job in 1 day, then the time taken by the person to finish the complete job is n days.  Another version of work is pool/tank problems where there is an inlet of water and an outlet as well.   If an inlet fills a tank in n hours, then it fills $\frac{1}{n}$th part of the tank in 1 hour. i.e. work done by it in 1 hour is $\frac{1}{n}$ If an outlet empties a full tank in m hours, then it will empty $\frac{1}{m}$th part of the tank in 1 hour. i.e. work done by it is $-\frac{1}{m}$ The concept is not hard to understand, however the application can be extremely tricky. So it would only help to solve as many problems as you can on this subject. Let's look at some examples. Ex 1. A copy machine can copy a paper in $36$ minutes. If a second copy machine were to be used at the same ...

Units digit of a number is the digit in the one's place of the number. For example, the units digit of $243$ is $3$. In competition math, you might come across occasional problems that ask you to find the units digit of an expression. These problems are more commonly found on Mathcounts Countdown Round. 1. The units digit of any number expressed as a power of $2$ repeats in the cycle $2, 4, 8, 6.$        $2^1 = 2, 2^2 = 4, 2^3 = 8, 2^4 = 16, 2^5 = 32, ....$ etc. 2. The units digit of any number expressed as a power of $3$ repeats in the cycle $3, 9, 7, 1.$        $3^1 = 3, 3^2 = 9, 4^3 = 27, 3^4 = 81, 3^5 = 243, ....$ etc. 3. The units digit of any number expressed as a power of $4$ is $4$ if the power is odd and $6$ if the power is even.        $4^1 = 4, 4^2 = 16, 4^3=64, 4^4=256, ....$ etc. 4. The units digit of any number expressed as a power of $5$ is always $5$.        $5^1...

Key Facts 1. Numbers of the form $\frac{p}{q}, q \neq 0$, where $p$ and $q$ are integers and those that can be expressed in the form of terminating or repeating decimals are called rational numbers .             Ex. $\frac{7}{32} = 0.21875, \frac{8}{15} = 0.5\bar{3}$ are rational numbers. 2. Properties of operations of rational numbers     For any rational numbers $a, b, c,$     (i) Rational numbers are closed under addition, multiplication, and subtraction.          $i.e., (a+b), (a-b),$ and $(a \cdot b)$ are all rational     (ii) Rational numbers follow the commutative law  of addition and multiplication.          $i.e., a + b = b + a$ and $a \cdot b = b \cdot a.$     (iii) Rational numbers follow the associative law of addition and multiplication,          $i.e., (a + b) + c = a + (b + c)$ and $(a \cdot b) \cdot c = ...

Coordinate Geometry is the study of geometry using algebraic tools like equations, relations, and operations. Before we start our deep dive, let's go over some basics of coordinate geometry. A coordinate grid consists of 2 perpendicular lines, which are called axes , and they are labeled like a number line would be. The horizontal axis is known as the x-axis , while the vertical axis is called the y-axis . The point of intersection of the two axes is known as the origin . The coordinate of the origin will always be $(0, 0)$. The numbers along the axes are used to locate points in the plane. The point at which a graph intersects the x-axis is known as the x - intercept  and the point of intersection with the y-axis is known as the y - intercept . The coordinates  also known as an Ordered Pair, is a set of values that expresses the distance a point lies from the origin. It is written in the format $(x, y)$ where $x$ is the value on the x-axis and the $y$ is the value on the ...

Now that you know the fundamentals of circles, let's take a look at some important circle theorems.  Inscribed angle is half the measure of the intercepted arc. An inscribed angle is the angle formed in the interior of a circle when two secant lines intersect on the circle.  The above theorem leads to an important result that comes handy in solving many geometry problems. The angle at the circumference subtended by a diameter is a right angle.  Simply put, the angle in a semicircle is a right angle.    All inscribed angles that intercept the same arc have the same measure.  The angle at the center is twice the angle at the circumference subtended by the same arc. The measure of the angle formed by the intersection of two chords is equal to the average of it's two corresponding arcs. Simply put, m$\angle \alpha = \frac{\overset{\LARGE{\frown}}{NP} + \overset{\LARGE{\frown}}{QO}}{2}$ Similar to the ...

The past 2 weeks that I have been away, were quite the adventure in the Grand Teton and the Yellowstone National Parks. As a family we have always loved spending time outdoors and this was the perfect trip right before the onset of my sophomore year. Getting back to life always seems so hard after a trip like that. Before I digress too much, lets get back to work. Today I would like to review the fundamentals of Circles. Let's first understand the different components of a Circle. Here are the key terms you should know. Radius - Line Segment from the center of the Circle to a point on the circumference. Diameter - Line Segment from one point on the circumference to another point on the circumference that passes through the center of the Circle. Needless to say, the length of the diameter is twice that of the radius. Area - The set of all points contained inside the circumference. Can be found using the formula $ \pi r^2$ where $r$ is the radius. ...

Let's take a look at right triangles and some of their special properties today. As a quick refresher, a right triangle is a triangle with a right angle. We can call the side opposite the right angle as the  hypotenuse , and the two sides adjacent to the $90^{\circ}$ angle as the  legs . In the image to the right, $AC$ is the hypotenuse, and the two legs are $AB$ and $BC$. Pythagorean Theorem One of the most famous and useful theorems in geometry is the Pythagorean Theorem. The theorem states that in right triangle $\triangle ABC$ with hypotenuse $c$ and legs $a$ and $b$, $$a^2+b^2=c^2$$ Lets apply this in a problem to see how it works.  Problem 1 : Let right triangle $\triangle ABC$ with right angle at $B$ have hypotenuse of $r+1$, and legs of length $7$ and $r$. Find $r$.  Solution:  We know that the sum of the squares of the legs is equal to the square of the hypotenuse. In other words, we have $$7^2 + r^2 = (r+1)^2.$$ Simplifying this a...