Page 1 of 2 WASHINGTON STATE MATHEMATICS COUNCIL 2018 MIDDLE SCHOOL MATH OLYMPIAD Session I: PROBLEM SOLVING Design, Operation and Maintenance of a Swimming Pool The City is planning to build a swimming pool for its rapidly growing community. The swimming pool is to be 2 m long and 12. m wide. The City first thought of building a pool that had water to a depth of 1. m. But they discarded that plan because community wanted a diving structure and pool was not sufficiently deep for that. The City planned a pool that had water to a depth of 3.6 m. But that was too expensive. Finally, the city decided to build a pool whose depth changed from one end to the other as shown in the figure below. The shallow end of the pool is to have water to a depth of 1. m; at least a 10 m length of the pool at this end needs to have water to depth of 1. m. The diving or deep end of the pool is to have water to a depth of 3.6 m; at least a 6 m length of the pool at the diving end needs to have water to a depth of 3.6 m. The depth of water is to increase gradually from 1. m to 3.6 m in central part of the pool. For the safety and comfort of the swimmers, the depth of the pool should not change by more than 1 m over a horizontal length of 3 m as shown in the figure. The water surface is 1 cm (or 0.1m) below the deck surrounding the pool. The City wanted a pool with the least volume that satisfies these requirements, because the cost of constructing and operating the pool increase with the volume of water in the pool. Your team needs
to decide on some dimensions of the side view. You will also need to calculate the volume of the water in the pool. For safety reasons, diving from the deck is allowed only at water depths of 2 m or more. There must be pool markings on the side walls and on the floor of the pool to indicate where the water is 2m deep. How far from the shallow end does the pool have water to a depth of 2 m? For safety reasons, there is a limit on the number of people who can be in the pool at one time. Safety regulations specify that each person needs 2. m 2 of water surface area if they are in the part of the pool that has water to a depth of more than 1. m; each person needs 0.93 m 2 of water surface area if they are in the part of the pool that has water to a depth of 1. m or less. What is the maximum number of people who can be in the pool at one time? Lap Cumulative time (minutes:seconds to the hundredth) 1 0:3.00 2 1:10.3 3 1:46.0 4 2:22.11 2:8.3 6 3:3.31 Jo, a 13 year old, has been training to be a competitive swimmer. Jo s coach noted the time it takes for Jo to swim each lap of the 100 m swim. A lap is defined as swimming from one end of the pool to the other end, lengthwise, and back for a total distance of 0 m in this case. The lap times for the first six laps, to the nearest hundredths of a second are given in table to the right. Use this information to find estimates of the lap time for the 30 th lap. Kim is responsible for creating the schedule for the pool for Saturday. Activities are to be scheduled in one hour slots, beginning on the hour, from 8:00 am until 8:00 pm. Kim needs to schedule 4 hours of lap swim, 2 hours of family swim/play in the shallow end and diving at the deep end (both scheduled at the same time), 3 hours of school swim teams, 3 hours for public swim. How many different schedules can Kim create if multiple hours of the same activity have to be scheduled consecutively?
Page 1 of Write the Responses Here. Show all of your work. Use the back of the pages if needed. Your work will be evaluated on: Your understanding of the problem The strategies that you used and your reasoning Your communication (both verbal and quantitative) of how you arrived at the solutions Your solutions and your checks for reasonableness of the solutions where appropriate. 1a: Determine the volume of water in the first pool that the City considered; the one with length 2 m, width 12. m and water to a depth of 1. m. (1 point for volume, 1 for showing how you calculated it.) Volume = 2 x 12. x 1. = 468.7 m 3 1b: Determine the volume of water in the second pool that the City considered; the one with length 2 m, width 12. m and water to a depth of 3.6 m. (1 point for volume, 1 for showing calculations.) Volume = 2 x 12. x 3.6 = 112 m 3 1c: Determine the dimensions of the pool that satisfies all the requirements of the City. (4@1 point for dimensions, @1 point for reasoning and/or calculations.) The length of the deep end is short as possible to minimize the volume; 6 m. The sloping floor is as steep as possible to minimize the volume; 1:3. The change in depth = 3.6 1. = 2.1 m The horizontal length of the sloping floor = 2.1 (1/3) = 6.3 m. The length of the shallow end = 2 6 6.3 = 12.7 m.
Page 2 of 1d: Determine the area of the side wall of the pool shown in 1c, that is below the water level. (1 point for area, 4@1 for reasoning and/or calculations.) Rectangle at the shallow end:- 12.7 x 1. = 19.0 m 2. Rectangle at the deep end:- 6 x 3.6 = 21.6 m 2. Central trapezoid:- 6.3 x (1. + 3.6)/2 = 16.06 m 2. Total area = 6.71 m 2. 1e: Determine the volume of water in the pool. You may round the volume of the pool to three significant digits. This means that you may express the answer in a form where only the three highest place digits can be non-zero, all lower place digits are zero. (1 point for volume, 1 for reasoning and/or calculations.) Is your answer reasonable when compared to your answers to 1a and 1b. (2 points reasoning) Volume of water = area of side x width = 6.71 x 12. = 708.937 m 3 = 709 m 3. Or (if they do it this way, they can recover any corresponding reasoning credit that they may have lost in 1d.) Volume of the shallow end:- 12.7 x 12. x 1. = 238.12 m 3. Volume of the deep end:- 6 x 12. x 3.6 = 270 m 3. Volume of the central trapezoidal prism:- 6.3 x 12. x (1. + 3.6)/2 = 200.812 m 3. Volume of water = 708.937 m 3 = 709 m 3. 468.7 m 3 < 709 m 3 < 112 m 3 ; the answer is reasonable. 2: Determine the distance from the shallow end to the line where the depth of water is 2 m. (1 point for distance, 3 for reasoning and/or calculations.)
Page 3 of 3: Determine the maximum number of bathers/swimmers who can be in the pool at the same time. Why are there different criteria for the parts of the pool depending on whether the depth of water is > 1. m or 1. m (1 point limit, 4 for reasoning and/or calculations. 2 points for plausible reasons for criteria) Water surface area where water depth 1. m:- 12.7 x 12. = 18.7 m 2. Limit to bathers who can stand in this part of the pool = 18.7 0.93 = 170.6 = 170 Rounding down to stay within limit. Water surface area where water depth > 1. m:- (6.3+6) x 12. = 13.7 m 2. Limit to bathers who can swim in this part of the pool = 13.7 2. = 61. = 61 Rounding down to stay within limit. The maximum number of bather allowed = 170 + 61 = 231. Accept 232 if they argue that the combined fractional spaces are sufficient for 1 more person. (1 point loss total for answer and reasoning if they round up prior to adding and give 233 as the limit.) A person will likely be swimming in the deeper depths and will be horizontal, need space lengthwise from toes to the extended finger tips and need space across for arms and feet to spread out depending on the stroke. Also need some separation between swimmers for safety. A person could stand in the shallower depths and will require less space.
Page 4 of 4a: Fill out the table below and use that information to calculate two estimates for Jo s lap time for the 30 th lap. (1 point each for the estimate, 2 points for each of the three columns of numbers, 1 point for each average, 2 points each for showing how to calculate the estimate for the 30 th lap time) Lap Cumulative time (minutes:seconds to the hundredths) mm:ss.ss Lap time (Seconds to the hundredths) ss.ss 1 0:3.00 3.00 Difference between current lap time and previous lap time (Seconds) Ratio between current lap time ad previous lap time To the thousandths 2 1:10.3 3.3 0.3 1.010 3 1:46.0 3.70 0.3 1.010 4 2:22.11 36.06 0.36 1.010 2:8.3 36.42 0.36 1.010 6 3:3.31 36.78 0.36 1.010 Average 0.36 1.010 Use the two averages computed above to find two estimates of the 30 th lap time Estimate 1 Estimate 2 30 Estimated lap time for the 30 th lap, to the hundredth of a second 4.32 sec 46.71 sec Assuming that the lap times increase linearly or are in an arithmetic sequence., the 30 th lap time = 3 + 0.36 x 29 = 4.62 seconds Assuming that the lap times increase at a constant ratio or are in a geometric sequence., the 30 th lap time = 3 x 1.01 29 = 46.71 seconds 4b: What should Jo s coach have done to allow you to decide which of these two methods was a better fit to Jo s lap times. (1 point) If Jo s coach had timed a few more laps, say 4 more laps, that would have been sufficient to decide whether either sequence as a good fit to the lap times.
Page of : Determine the number of different schedules Kim can create if multiple hours of the same activity must be scheduled consecutively. (1 point, 2 points for reasoning) If the multiple hours of the same activity have to be scheduled consecutively then there are four activities to be arranged; lap swim, family swim/play in the shallow end and diving at the deep end (both scheduled at the same time), school swim teams, and public swim The number of distinct schedules = 4! = 4 x 3 x 2 x 1 = 24