Personal Growth Official Guide For Gmat Quantitative Review Pdf


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of the test. THE OFFICIAL GUIDE FOR. GMAT® QUANTITATIVE REVIEW. 2ND EDITION. • Actual questions from past GMAT tests, including 75 questions new to . It is not a diet book but Healthy Weight Loss – Without Dieting. Following the In this effective Healthiest Way of E The Official Guide for GMAT Review 7 The Official Guide for GMAJ41' Quantitative Review 2nd Edition What Is the Content of the Test Like? It is important to recognize that the GMAT test.

Official Guide For Gmat Quantitative Review Pdf

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Views 35MB Size Report. DOWNLOAD PDF The Official Guide for GMAT Quantitative Review, 2nd Edition. Read more. GMAC. GMAT Official Guide Quantitative Review: Book + Online. Файл формата pdf; размером 6,78 МБ. Добавлен пользователем Zalt The GMAT Official Guide Quantitative Review provides targeted preparation for the mathematical portion of the GMAT exam. Designed by.

Official Transcripts. The overall acceptance rate for University of California-Los Angeles was reported as Table A U. Table 1: Lab History. Please note, we follow UCLA 4-year DDS Program admissions guidelines regarding limitations on accredited community college course work only 70 semester or quarter units will be accepted. International Non-U. So is it right for you? In the rankings released for , U. Would a undergrad from UCSB affect my chances?

If you are a pre med at UCSB, did you get into a good med school? Penn Dental Medicine seeks DMD applicants with a broad and strong educational background, who will have completed a four-year degree program prior to matriculation. Founded So while your state has one school, you're not getting the short end of the stick with regard to an acceptance to dental school. Out-of-state applicants go through the regular review processes along with applicants from California.

Law School , a ranking scheme that purports to use qualitative criteria instead of quantitative, ranks the law school fourteenth overall, tied with Duke, UCLA, and the University of Texas. Data reported includes admissions, enrollment, diversity, and number and type of degrees awarded. This is where achievements are born.

The UCLA School of Dentistry was established in in response to the need for an additional public school of dentistry in the greater Los Angeles area.

Dental services and ucla dental. Office of Admissions and Recruitment. The information on this Web site is not to be regarded as creating a binding contract between the student and the dental school. Most schools advertise a requirement or 16 to 20 as minimum overall scores from the available 30 marks.

The best part of my job is being a part of their development — I am inspired everyday by work they do and consider myself honored to partner with and train such a diverse, talented, and committed group. UCLA offers graduate degrees in nearly departments, ranging from an extensive selection of business and medical programs to degrees in 40 The MS program is tailored to dental hygienists who wish to undertake rigorous scholarship, learn teaching skills and assume leadership positions.

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Therefore, the services of a dentist are a necessary and even inevitable thing in our life. Basic science coursework that is older than five years may be considered obsolete. The ranking aims to provide a useful resource for prospective students seeking the top universities for dentistry across the globe. It is home to the quarterly Schedule of Classes, the General Catalog, important dates and deadlines, fee information, and more. What makes a successful applicant? Approximately students may be admitted to entering classes of the School of Dentistry.

A total of 11, people applied. Dugoni School of Dentistry reserves the right to modify or change admissions standards or requirements any time without prior notice. While a foundation in science is desirable preparation for dental school, well-prepared candidates also possess course work in humanities, social science, and the arts. University of California—Los Angeles is a public institution that was founded in And so the ucla dental is in such demand among people.

Students applying to dental schools from the University of Connecticut in the past several years have had a The curriculum of the Doctor of Dental Surgery program is structured to present basic science courses during the first two years, with some clinical experience beginning in the first year and increasing each year until it predominates in the junior and senior years.

There are many directions in dentistry. Upon acceptance and prior to matriculation, official transcripts must be sent directly to the School of Dentistry from each undergraduate and graduate institution attended, and must verify sufficient credits and correct courses.

The UCLA Career Center offers personal assistance and programs on the graduate and professional school application process, including program selection, the personal statement, faculty recommendations, admissions tests, and financial assistance. If you already have the earlier editions, by all means, use those first. All of the Official Guide practice sets are created by the same folks who make the real exam, and are even taken from actual past tests.

Past tests are the only source for the Verbal, Quant, and IR questions, though.

Admittedly, a version of the score guide is buried on the GMAC website, but the wording is slightly outdated, and the guide is inconveniently separate from all of the other materials on MBA. This three volume set does have some minor shortcomings. The tutorial and advice portions of the book are short and dry. And the answer explanations are frequently inadequate.

All that is very important. If you are starting from scratch, you might as well start with the newest. Discrete Probability 6. Percents Section 3. The topics included are as follows: Simplifying Algebraic Expressions 7. Exponents 2. Equations 8. Inequalities 3. Solving Linear Equations with One Unknown 9. Absolute Value 4.

Solving Two Linear Equations with Functions Two Unknowns 5. Solving Equations by Factoring 6. Solving Q! Extensive knowledge of theorems and the ability to construct proofs, skills that are usually developed in a formal geometry course, are not tested.

The topics included in this section are the following: Lines 6. Triangles 2. Intersecting Lines and Angles 7. Perpendicular Lines 8. Circles 4. Parallel Lines 9. Rectangular Solids and Cylinders 5. Polygons Convex Coordinate Geometry Section 3. Rate Problems 6. Profit 2. Work Problems 7. Sets 3. Mixture Problems 8. Geometry Problems 4. Interest Problems 9. Measurement Problems 5. Discount Properties of Integers An integer is any number in the set[ In this case, y is also said to be divisible by x or to be a multiple of x.

Note that y is divisible by x if and only if the remainder r is 0; for example, 32 has a remainder of 0 when divided by 8 because 32 is divisible by 8. Also, note that when a smaller integer is divided by a larger integer, the quotient is 0 and the remainder is the smaller integer. Any integer that is divisible by 2 is an even integer; the set of even integers is [.

Integers that are not divisible by 2 are odd integers; [. If at least one factor of a product of integers is even, then the product is even; otherwise the product is odd. If two integers are both even or both odd, then their sum and their difference are even.

Otherwise, their sum and their difference are odd. A prime number is a positive integer that has exactly two different positive divisors, 1 and itself. For example, 2, 3, 5, 7, 11, and 13 are prime numbers, but 15 is not, since 15 has four different positive divisors, 1, 3, 5, and The number 1 is not a prime number since it has only one positive divisor.

Every integer greater than 1 either is prime or can be uniquely expressed as a product of prime factors. The numbers -2, -1, 0, 1, 2, 3, 4, 5 are consecutive integers. The numbers 0, 2, 4, 6, 8 are consecutive even integers, and 1, 3, 5, 7, 9 are consecutive odd integers.

Properties ofthe integer 1. Properties ofthe integer 0. The integer 0 is neither positive nor negative. Division by 0 is not defined. Fractions In a fraction ;. The denominator of a fraction can never be 0, because division by 0 is not defined. Two fractions are said to be equivalent if they represent the same number.

For example, and 14 are equivalent since thev both represent the number l. In each case, the fraction is reduced to The gcd of 8 and 36 is 4 and the gcd of 14 and 63 is 7. Addition and subtraction of fractions. Two fractions with the same denominator can be added or subtracted by performing the required operation with the numerators, leaving the denominators the same. If two fractions do not have the same denominator, express them as 5 77 7 7 3 4 equivalent fractions with the same denominator.

For example, to addS and 7' multiply the numerator and denominator of the first fraction by 7 and the numerator and denominator of the second flract1on. To multiply two fractions, simply multiply the two numerators and multiply the two denominators. In general, the reciprocal of a fraction! A number that consists of a whole number and a fraction, for example, 71, is a mixed number: Decimals In the decimal system, the position of the period or decimal point determines the place value of the digits.

For example, the digits in the number 7, F 7 6 5 4 3 2 1 Some examples of decimals follow. This is called scientific notation. For example, can be written as 2. The decimal point is moved to the right if the exponent is positive and to the left if the exponent is negative. For example, 2. To add or subtract two decimals, the decimal points of both numbers should be lined up. If one of the numbers has fewer digits to the right of the decimal point than the other, zeros may be inserted to the right of the last digit.

For example, to add To multiply decimals, multiply the numbers as if they were whole numbers and then insert the decimal point in the product so that the number of digits to the right of the decimal point is equal to the sum of the numbers of digits to the right of the decimal points in the numbers being multiplied.

For example: To divide a number the dividend by a decimal the divisor , move the decimal point of the divisor to the right until the divisor is a whole number. Then move the decimal point of the dividend the same number of places to the right, and divide as you would by a whole number.

The decimal point in the quotient will be directly above the decimal point in the new dividend. For example, to divide Real Numbers All real numbers correspond to points on the number line and all points on the number line correspond to real numbers.

All real numbers except zero are either positive or negative. If n is "between 1 and 4, inclusive," then 1 s n s 4. The distance between a number and zero on the number line is called the absolute value of the number. Thus 3 and -3 have the same absolute value, 3, since they are both three units from zero. Note that the absolute value of any nonzero number is positive.

Here are some properties of real numbers that are used frequently. Ratio and Proportion The ratio of the number a to the number b b. A ratio may be expressed or represented in several ways. For example, the ratio of 2 to 3 can be written as 2 to 3, 2: The order of the terms of a ratio is important.

For example, the ratio of the number of months with exactly 30 days to the number with exactly 31 days is. Percents Percent means per hundred or number out of A percent can be represented as a fraction with a denominator of , or as a decimal.

The percent 0. For example, 0. Percent change. Often a problem will ask for the percent increase or decrease from one quantity to another quantity. In the example above the percent increase would be found in the following way: Note that the percent increase from 24 to 30 is not the same as the percent decrease from 30 to In the following example, the increase is greater than percent: If the cost of a certain house in was percent of its cost in , by what percent did the cost increase?

Powers and Roots of Numbers When a number k is to be used n times as a factor in a product, it can be expressed as kn, which means the nth power of k. Squaring a number that is greater than 1, or raising it to a higher power, results in a larger number; squaring a number between 0 and 1 results in a smaller number.

The square root of a negative number is not a real number. Every positive number n has two square roots, one positive and the other negative, but fn denotes thsrositive number whose square is n. For example, J9 denotes 3.

The two square roots of 9 are J9 Every real number r has exactly one real cube root, which is the number s such that s 3 r. The real cube root of r is denoted by. Descriptive Statistics A list of numbers, or numerical data, can be described by various statistical measures. One of the most common of these measures is the average, or arithmetic mean, which locates a type of"center" for the data. The average of n numbers is defined as the sum of the n numbers divided by n.

The median is another type of center for a list of numbers. To calculate the median of n numbers, first order the numbers from least to greatest; if n is odd, the median is defined as the middle number, whereas if n is even, the median is defined as the average of the two middle numbers. In the example above, the numbers, in order, are 4, 4, 6, 7, 10, and the median is 6, the middle number.

Note that the mean of these numbers is 7. The median of a set of data can be less than, equal to, or greater than the mean. Note that for a large set of data for example, the salaries of company employees , it is often true that about half of the data is less than the median and about half of the data is greater than the median; but this is not always the case, as the following data show. The mode of a list of numbers is the number that occurs most frequently in the list.

For example, the mode of 1, 3, 6, 4, 3, 5 is 3. A list of numbers may have more than one mode. For example, the list 1, 2, 3, 3, 3, 5, 7, 10, 10, 10, 20 has two modes, 3 and The degree to which numerical data are spread out or dispersed can be measured in many ways.

The simplest measure of dispersion is the range, which is defined as the greatest value in the numerical data minus the least value. Note how the range depends on only two values in the data. One of the most common measures of dispersion is the standard deviation.

Generally speaking, the more the data are spread away from the mean, the greater the standard deviation. The standard deviation of n numbers can be calculated as follows: Shown below is this calculation for the data 0, 7, 8, 10, 10, which have arithmetic mean 7. This is why a distribution with data grouped closely around the mean will have a smaller standard deviation than will data spread far from the mean. To illustrate this, compare the data 6, 6, 6.

Note that the numbers in the second set of data seem to be grouped more closely around the mean of 7 than the numbers in the first set.

This is reflected in the standard deviation, which is less for the second set approximately 1. There are many ways to display numerical data that show how the data are distributed.

One simple way is with a frequency distribution, which is useful for data that have values occurring with varying frequencies. For example, the 20 numbers -4 0 0 -3 -2 -1 -1 0 -1 -4 -1 -5 0 -2 0 -5 -2 0 0 -1 are displayed on the next page in a frequency distribution by listing each different value x and the frequency f with which x occurs.

Sets In mathematics a set is a collection of numbers or other objects. The objects are called the elements of the set. If S is a set having a finite number of elements, then the number of elements is denoted by lsi. The intersection of A and B is the set of all elements that are both in A and in B. Two sets that have no elements in common are said to be disjoint or mutually exclusive. The relationship between sets is often illustrated with a Venn diagram in which sets are represented by regions in a plane.

For two sets Sand T that are not disjoint and neither is a subset of the other, the intersection S n T is represented by the shaded region of the diagram below. S T This diagram illustrates a fact about any two finite sets S and T: This counting method is called the general addition rule for two sets. Counting Methods There are some useful methods for counting objects and sets of objects without actually listing the elements to be counted. The following principle of multiplication is fundamental to these methods.

If an object is to be chosen from a set of m objects and a second object is to be chosen from a different set of n objects, then there are mn ways of choosing both objects simultaneously. As an example, suppose the objects are items on a menu. As another example, each time a coin is flipped, there are two possible outcomes, heads and tails. If an experiment consists of 8 consecutive coin flips, then the experiment has 2 8 possible outcomes, where each of these outcomes is a list of heads and tails in some order.

A symbol that is often used with the multiplication principle is the factorial. If n is an integer greater than 1, then n factorial, denoted by the symbol n! Therefore, 2! Also, by definition, 0! The factorial is useful for counting the number of ways that a set of objects can be ordered. If a set of n objects is to be ordered from 1st to nth, then there are n choices for the 1st object, n - 1 choices for the 2nd object, n - 2 choices for the 3rd object, and so on, until there is only 1 choice for the nth object.

For example, the number of ways of ordering the letters A, B, and C is 3! These orderings are called the permutations of the letters A, B, and C. A permutation can be thought of as a selection process in which objects are selected one by one in a certain order.

If the order of selection is not relevant and only k objects are to be selected from a larger set of n objects, a different counting method is employed.

Then the number of possible complete selections of k objects is called the number of combinations of n objects taken kat a time and is denoted by: Note that: In general,: Discrete Probability Many of the ideas discussed in the preceding three topics are important to the study of discrete probability.

Discrete probability is concerned with experiments that have a finite number of outcomes. Given such an experiment, an event is a particular set of outcomes. For example, rolling a number cube with faces numbered 1 to 6 similar to a 6-sided die is an experiment with 6 possible outcomes: The probability that an event E occurs, denoted by P E , is a number between 0 and 1, inclusive. Two events A and Bare said to be independent if the occurrence of either event d? Therefore, A and B are independent.

The following multiplication rule holds for any independent events E and F: Also, suppose that events Aand Bare mutually exclusive and events B and Care independent. Thus, one can conclude that 0. Letters such as x or n are used to represent unknown quantities. For example, suppose Pam has 5 more pencils than Fred.

Such an expression is called a second degree or quadratic polynomial in x since the highest power of xis 2. The expression 3x 2 is not a polynomial because it is not a sum of terms that are each powers of x multiplied 2x- 5 by coefficients. Simplifying Algebraic Expressions Often when working with algebraic expressions, it is necessary to simplify them by factoring or combining like terms. In the expression 9x- 3 y, 3 is a factor common to both terms: If there are common factors in the numerator and denominator of an expression, they can be divided out, provided that they are not equal to zero.

Equations A major focus of algebra is to solve equations involving algebraic expressions. An equation may have no solution or one or more solutions. If two or more equations are to be solved together, the solutions must satisfy all the equations simultaneously. Two equations having the same solution s are equivalent equations. Note that the second equation is the first equation multiplied by 2. Solving Linear Equations with One Unknown To solve a linear equation with one unknown that is, to find the value of the unknown that satisfies the equation , the unknown should be isolated on one side of the equation.

This can be done by performing the same mathematical operations on both sides of the equation.

Remember that if the same number is added to or subtracted from both sides of the equation, this does not change the equality; likewise, multiplying or dividing both sides by the same nonzero number does not change the equality. Solving Two Linear Equations with Two Unknowns For two linear equations with two unknowns, if the equations are equivalent, then there are infinitely many solutions to the equations, as illustrated at the end of section 3.

If the equations are not equivalent, then they have either one unique solution or no solution. The latter case is illustrated by the two equations: Thus, no values of x andy can simultaneously satisfy both equations. There are several methods of solving two linear equations with two unknowns. Otherwise, a unique solution can be found. One way to solve for the two unknowns is to express one of the unknowns in terms of the other using one of the equations, and then substitute the expression into the remaining equation to obtain an equation with one unknown.

This equation can be solved and the value of the unknown substituted into either of the original equations to find the value of the other unknown. For example, the following two equations can be solved for x andy. There is another way to solve for x andy by eliminating one of the unknowns. This can be done by making the coefficients of one of the unknowns the same disregarding the sign in both equations and either adding the equations or subtracting one equation from the other. These answers can be checked by substituting both values into both of the original equations.

Solving Equations by Factoring Some equations can be solved by factoring. To do this, first add or subtract expressions to bring all the expressions to one side of the equation, with 0 on the other side. Then try to factor the nonzero side into a product of expressions. If this is possible, then using property 7 in section 3. The solutions of the simpler equations will be solutions of the factored equation. A fraction equals 0 if and only if its numerator x-4 equals 0.

Thus, the solutions are 0 and 3. The solutions of an equation are also called the roots of the equation. These roots can be checked by substituting them into the original equation to determine whether they satisfy the equation.

Jb 2 - 4ac and -b-. Jb 2 - 4ac is not a 2a real number and the equation has no real roots. Exponents A positive integer exponent of a number or a variable indicates a product, and the positive integer is the number of times that the number or variable is a factor in the product.

For example, x 5 means x x x x x ; that is, x is a factor in the product 5 times. Some rules about exponents follow. Let x andy be any positive numbers, and let rand s be any positive integers. It can be shown that rules also apply when rands are not integers and are not positive, that is, when r and s are any real numbers. Inequalities An inequality is a statement that uses one of the following symbols: As in solving an equation, the same number can be added to or subtracted from both sides of the inequality, or both sides of an inequality can be multiplied or divided by a positive number without changing the truth of the inequality.

However, multiplying or dividing an inequality by a negative number reverses the order of the inequality.

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Functions An algebraic expression in one variable can be used to define a function of that variable. A function is denoted by a letter such as for g along with the variable in the expression. In any function there can be no more than one output for any given input.

The set of all allowable inputs for a function is called the domain of the function. Forf and g defined above, the domain off is the set of all real numbers and the domain of g is the set of all numbers greater than The domain of a function can consist of only the positive integers and possibly 0. Lines In geometry, the word "line" refers to a straight line that extends without end in both directions.

The part of the line from P to Q is called a line segment. P and Q are the endpoints of the segment. Intersecting Lines and Angles If two lines intersect, the opposite angles are called vertical angles and have the same measure. Perpendicular Lines An angle that has a measure of90 o is a right angle. If two lines intersect at right angles, the lines are perpendicular.

Parallel Lines If two lines that are in the same plane do not intersect, the two lines are parallel. Polygons Convex A polygon is a closed plane figure formed by three or more line segments, called the sides of the polygon.

Each side intersects exactly two other sides at their endpoints. The points of intersection of the sides are vertices.

The following figures are polygons: Note that a pentagon can be partitioned into three triangles and therefore the sum of the angle measures can be found by adding the sum of the angle measures of three triangles. The perimeter of a polygon is the sum of the lengths of its sides. The commonly used phrase "area of a triangle" or any other plane figure is used to mean the area of the region enclosed by that figure.

Triangles There are several special types of triangles with important properties. But one property that all triangles share is that the sum of the lengths of any two of the sides is greater than the length of the third side, as illustrated below. All angles of an equilateral triangle have equal measure. An isosceles triangle has at least two sides of the same length. If two sides of a triangle have the same length, then the two angles opposite those sides have the same measure.

Conversely, if two angles of a triangle have the same measure, then the sides opposite those angles have the same length. In a right triangle, the side opposite the right angle is the hypotenuse, and the other two sides are the legs.

An important theorem concerning right triangles is the Pythagorean theorem, which states: In a right triangle, the square of the length of the hypotenuse is equal to the sum of the squares of the lengths of the legs. Any triangle in which the lengths of the sides are in the ratio 3: For example, in tl.

The altitude of a triangle is the segment drawn from a vertex perpendicular to the side opposite that vertex. Relative to that vertex and altitude, the opposite side is called the base.

The area of a triangle is equal to: The area of tl. Similarly, any altitude of an equilateral triangle bisects the side to which it is drawn. The area of 6. Quadrilaterals A polygon with four sides is a quadrilateral. A quadrilateral in which both pairs of opposite sides are parallel is a parallelogram.

The opposite sides of a parallelogram also have equal length. A parallelogram with right angles is a rectangle, and a rectangle with all sides of equal length is a square.

The area of trapezoid PQRS may be calculated as follows: Circles A circle is a set of points in a plane that are all located the same distance from a fixed point the center of the circle. A chord of a circle is a line segment that has its endpoints on the circle.

A chord that passes through the center of the circle is a diameter of the circle. A radius of a circle is a segment from the center of the circle to a point on the circle. The words "diameter" and "radius" are also used to refer to the lengths of these segments.

The circumftrence of a circle is the distance around the circle. If r is the radius of the circle, then the circumference is equal to 2nr, where: The area of a circle of radius r is 7 equa1 to nr. PR is a diameter and OR is a radius.

The number of degrees of arc in a circle or the number of degrees in a complete revolution is A line that has exactly one point in common with a circle is said to be tangent to the circle, and that common point is called the point oftangency. A radius or diameter with an endpoint at the point of tangency is perpendicular to the tangent line, and, conversely, a line that is perpendicular to a radius or diameter at one of its endpoints is tangent to the circle at that endpoint.

If each vertex of a polygon lies on a circle, then the polygon is inscribed in the circle and the circle is circumscribed about the polygon. If each side of a polygon is tangent to a circle, then the polygon is circumscribed about the circle and the circle is inscribed in the polygon. If a triangle is inscribed in a circle so that one of its sides is a diameter of the circle, then the triangle is a right triangle. Rectangular Solids and Cylinders A rectangular solid is a three-dimensional figure formed by 6 rectangular surfaces, as shown below.

Each rectangular surface is a foce. Each solid or dotted line segment is an edge, and each point at which the edges meet is a vertex. A rectangular solid has 6 faces, 12 edges, and 8 vertices. Opposite faces are parallel rectangles that have the same dimensions. A rectangular solid in which all edges are of equal length is a cube. The surfoce area of a rectangular solid is equal to the sum of the areas of all the faces. The volume is equal to length x width x height ; in other words, area of base x height.

In the rectangular solid above, the dimensions are 3, 4, and 8. The figure above is a right circular cylinder. The two bases are circles of the same size with centers 0 and P, respectively, and altitude height OP is perpendicular to the bases.

The surface area of a right circular cylinder with a base of radius rand height his equal to 2. The volume of a cylinder is equal to nr 2 h, that is, area of base x height. The horizontal line is called the x-axis and the perpendicular vertical line is called they-axis. The point at which these two axes intersect, designated 0, is called the origin. Each point in the plane has an x-coordinate and a y-coordinate. A point is identified by an ordered pair x,y of numbers in which the x-coordinate is the first number and they-coordinate is the second number.

Similarly, the xV' coordinates of point Q are -4, The origin 0 has coordinates 0,0. One way to find the distance between two points in the coordinate plane is to use the Pythagorean theorem. One can verify this for the points -2,2 , 2,0 , and 0,1 by substituting the respective coordinates for x andy in the equation.

For any two points on the line, the slope is defined to be the ratio of the difference in they-coordinates to the difference in the x-coordinates. They-intercept is they-coordinate of the point at which the line intersects they-axis. The x-intercept is the x-coordinate of the point at which the line intersects the x-axis.

Thus, the x-intercept is 2. For example, consider the points -2,4 and 3,-3 on the line below. They-intercept is lThe x-intercept can be found as follows: If the slope of a line is negative, the line slants downward from left to right; if the slope is positive, the line slants upward. There is a connection between graphs of lines in the coordinate plane and solutions of two linear equations with two unknowns. If two linear equations with unknowns x andy have a unique solution, then the graphs of the equations are two lines that intersect in one point, which is the solution.

If the equations are equivalent, then they represent the same line with infinitely many points or solutions. If the equations have no solution, then they represent parallel lines, which do not intersect. There is also a connection between functions see section 3. If a function is graphed in the coordinate plane, the function can be understood in different and useful ways.

Similarly, any function f x can be graphed by equating y with the value of the function: One can plot several points x,f x on the graph to understand the connection between a function and its graph: The following discussion of word problems illustrates some of the techniques and concepts used in solving such problems.

Example 1: If a car travels at an average speed of 70 kilometers per hour for 4 hours, how many kilometers does it travel? Thus, the car travels kilometers in 4 hours. To determine the average rate at which an object travels, divide the total distance traveled by the total amount of traveling time.

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Example 2: On a mile trip, Car X traveled half the distance at 40 miles per hour mph and the other half at 50 mph.

What was the average speed of Car X? First it is necessary to determine the amount of traveling time.

Some rate problems can be solved by using ratios. Example 3: Cross multiplication results in the equation Solution: Work Problems In a work problem, the rates at which certain persons or machines work alone are usually given, and it is necessary to compute the rate at which they work together or vice versa. The reasoning is that in 1 hour Rae does 1 of the job, Sam does 1 of the job, and Rae and Sam together do 1 of r s h the job. If Machine X can produce 1, bolts in 4 hours and Machine Y can produce 1, bolts in 5 hours, in how many hours can Machines X andY, working together at these constant rates, produce 1, bolts?

If Art and Rita can do a job in 4 hours when working together at their respective constant rates and Art can do the job alone in 6 hours, in how many hours can Rita do the job alone? Mixture Problems In mixture problems, substances with different characteristics are combined, and it is necessary to determine the characteristics of the resulting mixture.

How many liters of a solution that is 15 percent salt must be added to 5 liters of a solution that is 8 percent salt so that the resulting solution is 10 percent salt?With an acceptance rate of In the rectangular coordinate system above, the Work the problem.

The Official Guide for GMAT Review

Last visit was: Global notifications Settings Mark All Read. Remember, getting accepted to dental school is a big undertaking. GMAT scores are used by admissions officers in roughly 1, graduate business and management programs worldwide. There are many directions in dentistry.

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Also read my other articles. I am highly influenced by becoming a child advocate. I am fond of reading books intently .