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15.6: Problems

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    1 . How many cubic inches are there in a cubic foot? The answer is not 12.

    2. Assume a dog's brain is twice is great in diameter as a cat's, but each animal's brain cells are the same size and their brains are the same shape. In addition to being a far better companion and much nicer to come home to, how many times more brain cells does a dog have than a cat? The answer is not 2 .

    3 . The population density of Los Angeles is about 4000 people \(/ \mathrm{km}^2\). That of San Francisco is about 6000 people \(/ \mathrm{km}^2\). How many times farther away is the average person's nearest neighbor in LA than in San Francisco? The answer is not 1.5 .
    4. A hunting dog's nose has about 10 square inches of active surface. How is this possible, since the dog's nose is only about 1 in x 1 in x 1 in \(=1 \mathrm{in}^3\) ? After all, 10 is greater than 1 , so how can it fit?

    5. Estimate the number of blades of grass on a football field.

    6. In a computer memory chip, each bit of information (a 0 or a 1 ) is stored in a single tiny circuit etched onto the surface of a silicon chip. A typical chip stores 64 Mb (megabytes) of data, where a byte is 8 bits. Estimate (a) the area of each circuit, and (b) its linear size.

    7. Suppose someone built a gigantic apartment building, measuring 10 km \(\times 10 \mathrm{~km}\) at the base. Estimate how tall the building would have to be to have space in it for the entire world's population to live.

    8. A hamburger chain advertises that it has sold 10 billion Bongo Burgers. Estimate the total mass of hay required to feed the cows used to make the burgers.

    9. Estimate the volume of a human body, in \(\mathrm{cm}^3\).

    10. S . How many \(\mathrm{cm}^2\) is \(1 \mathrm{~mm}^2\) ?

    11. S. Compare the light-gathering powers of a \(3-\mathrm{cm}\)-diameter telescope and a \(30-\mathrm{cm}\) telescope.

    12. S. One step on the Richter scale corresponds to a factor of 100 in terms of the energy absorbed by something on the surface of the Earth, e.g. a house. For instance, a 9.3-magnitude quake would release 100 times more energy than an 8.3. The energy spreads out from the epicenter as a wave, and for the sake of this problem we'll assume we're dealing with seismic waves that spread out in three dimensions, so that we can visualize them as hemispheres spreading out under the surface of the earth. If a certain 7.6magnitude earthquake and a certain 5.6-magnitude earthquake produce the same amount of vibration where I live, compare the distances from my house to the two epicenters.

    15.6: Problems is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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