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Chapter 1: Problem 22

Allometry is the study of the relative size of different parts of a body as a consequence of growth. In this problem, you will check the accuracy of an allometric equation: the weight of a fish is proportional to the cube of its length. \(^{87}\) Table 1.40 relates the weight, \(y,\) in \(\mathrm{gm}\), of plaice (a type of fish) to its length, \(x,\) in \(\mathrm{cm} .\) Does this data support the hypothesis that (approximately) \(y=k x^{3} ?\) If so, estimate the constant of proportionality, \(k\) $$\begin{array}{r|r|r|r|r|r} \hline x & y & x & y & x & y \\ \hline 33.5 & 332 & 37.5 & 455 & 41.5 & 623 \\ 34.5 & 363 & 38.5 & 500 & 42.5 & 674 \\ 35.5 & 391 & 39.5 & 538 & 43.5 & 724 \\ 36.5 & 419 & 40.5 & 574 & & \\ \hline \end{array}$$

Short Answer

Expert verified
The data supports the hypothesis; estimated \( k \approx 0.00876 \).

Step by step solution

01

Understand the equation y = kx^3

We need to test if the relationship between the weight and length of the fish is approximately represented by the equation \( y = kx^3 \), where \( k \) is a constant of proportionality. This implies that the weight \( y \) of the fish should be proportional to the cube of its length \( x \).
02

Calculate x^3 for each x value

Compute the cube of each length \( x \) given in the table: \( x = 33.5, 34.5, 35.5, ... , 43.5 \).- \( 33.5^3 = 37517.375 \)- \( 34.5^3 = 41093.625 \)- \( 35.5^3 = 44692.375 \)- \( 36.5^3 = 48402.625 \)- \( 37.5^3 = 52734.375 \)- \( 38.5^3 = 57096.625 \)- \( 39.5^3 = 61509.375 \)- \( 40.5^3 = 65972.625 \)- \( 41.5^3 = 71527.375 \)- \( 42.5^3 = 76568.125 \)- \( 43.5^3 = 82318.875 \)
03

Calculate k for each pair of (x^3, y) values

For each pair of \( (x^3, y) \), calculate \( k \) using the equation \( k = \frac{y}{x^3} \).- For \( x = 33.5, k = \frac{332}{37517.375} \approx 0.00884 \)- For \( x = 34.5, k = \frac{363}{41093.625} \approx 0.00883 \)- For \( x = 35.5, k = \frac{391}{44692.375} \approx 0.00875 \)- For \( x = 36.5, k = \frac{419}{48402.625} \approx 0.00866 \)- For \( x = 37.5, k = \frac{455}{52734.375} \approx 0.00863 \)- For \( x = 38.5, k = \frac{500}{57096.625} \approx 0.00876 \)- For \( x = 39.5, k = \frac{538}{61509.375} \approx 0.00875 \)- For \( x = 40.5, k = \frac{574}{65972.625} \approx 0.00870 \)- For \( x = 41.5, k = \frac{623}{71527.375} \approx 0.00871 \)- For \( x = 42.5, k = \frac{674}{76568.125} \approx 0.00880 \)- For \( x = 43.5, k = \frac{724}{82318.875} \approx 0.00880 \)
04

Analyze the values of k

Looking at the calculated values of \( k \), they are all approximately in the range of 0.00863 to 0.00884. This consistent pattern suggests that \( y \) is indeed proportional to \( x^3 \).
05

Estimate the constant of proportionality k

Estimate \( k \) by averaging the individual \( k \) values obtained. The average is: \[ k \approx \frac{0.00884 + 0.00883 + 0.00875 + 0.00866 + 0.00863 + 0.00876 + 0.00875 + 0.00870 + 0.00871 + 0.00880 + 0.00880}{11} \approx 0.00876 \]

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Proportional Relationships
Understanding proportional relationships is essential in many fields, including biology and physics. In a proportional relationship, two quantities increase or decrease together at the same rate. This means that if one quantity doubles, the other also doubles, maintaining a constant ratio between them.
For instance, in the context of the allometry exercise, we hypothesize that the weight of a fish (\( y \)) is proportional to the cube of its length (\( x^3 \)). This relationship is expressed mathematically as \( y = kx^3 \). Here \( k \) is a constant – a fixed number that specifies the exact proportionality relationship for these variables.
To determine if the hypothesis holds true, we must check if the ratio \( \frac{y}{x^3} \) remains approximately constant across various lengths and weights.
  • A consistent ratio suggests a proportional relationship.
  • An inconsistent ratio indicates other factors might be at play.
Proportional relationships are visually represented by a straight line if you plot one quantity against the other, but since we deal with \( x^3 \) instead of \( x \), the plot involves nonlinear scaling.
Allometric Equation
The allometric equation is a specific form of a power-law relationship used to describe how characteristics of living organisms change with size. It can be expressed in the form \( y = kx^a \), where \( k \) and \( a \) are constants. In biology, these relationships often describe how one biological variable, such as mass, varies with another, like length.
The exercise focuses on the hypothesis that fish weight is proportional to the cube of its length, implying a power of three. Therefore, the allometric equation simplifies to \( y = kx^3 \), where \( y \) is the fish's weight, and \( x \) is its length.
To apply this equation:
  • Calculate the cube of the fish's length for each instance in the data.
  • Check each calculated weight against these values using the equation.
If the relationship holds, it means biological growth processes within the fish species maintain this specific proportional pattern. Allometric equations help scientists understand growth dynamics and can be applied to many other contexts in biology.
Constant of Proportionality
The constant of proportionality is a crucial component in proportional relationships. It indicates how much one quantity changes in relation to another. In our allometric equation \( y = kx^3 \), \( k \) represents this constant and is central to defining the relationship between the fish's length and weight.
In this problem, to find \( k \), divide the weight \( y \) by the cube of the length \( x^3 \) for each data point. This gives different \( k \) values for each pair of measurements.
  • Compute \( k = \frac{y}{x^3} \)
  • Examine the variation across calculated values
  • A minimal variation indicates a strong consistent proportionality
A consistent value of \( k \) across different sets of data would confirm the allometric hypothesis. By averaging these values, you get an estimate for \( k \), allowing predictions of fish weight for other lengths.

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Most popular questions from this chapter

Table 1.43 gives values for \(g(t),\) a periodic function. (a) Estimate the period and amplitude for this function. (b) Estimate \(g(34)\) and \(g(60)\). Table 1.43 $$\begin{array}{|c|c|c|c|c|c|c|c|c|}\hline t & 0 & 2 & 4 & 6 & 8 & 10 & 12 & 14 \\\\\hline g(t) & 14 & 19 & 17 & 15 & 13 & 11 & 14 & 19 \\\\\hline t & 16 & 18 & 20 & 22 & 24 & 26 & 28 & \\\\\hline g(t) & 17 & 15 & 13 & 11 & 14 & 19 & 17 \\\\\hline\end{array}$$

A city's population is 1000 and growing at \(5 \%\) a year. (a) Find a formula for the population at time \(t\) years from now assuming that the \(5 \%\) per year is an: (i) Annual rate (ii) Continuous annual rate (b) In each case in part (a), estimate the population of the city in 10 years.

In 2010 , there were about 246 million vehicles (cars and trucks) and about 308.7 million people in the US. \(^{70}\) The number of vehicles grew \(15.5 \%\) over the previous decade, while the population has been growing at \(9.7 \%\) per decade. If the growth rates remain constant, when will there be, on average, one vehicle per person?

The number of species of lizards, \(N,\) found on an island off Baja California is proportional to the fourth root of the area, \(A,\) of the island. \(^{85}\) Write a formula for \(N\) as a function of \(A .\) Graph this function. Is it increasing or decreasing? Is the graph concave up or concave down? What does this tell you about lizards and island area?

A company produces and sells shirts. The fixed costs are 7000 dollars and the variable costs are 5 dollars per shirt. (a) Shirts are sold for 12 dollars each. Find cost and revenue as functions of the quantity of shirts, \(q\) (b) The company is considering changing the selling price of the shirts. Demand is \(q=2000-40 p\) where \(p\) is price in dollars and \(q\) is the number of shirts. What quantity is sold at the current price of $$ 12 ?\( What profit is realized at this price? (c) Use the demand equation to write cost and revenue as functions of the price, \)p .$ Then write profit as a function of price. (d) Graph profit against price. Find the price that maximizes profits. What is this profit?
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