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Chapter 10: Problem 1

Body mass index (or BMI) is often used as an indicator for whether a person is over- or underweight. A person's BMI is calculated from their mass (in \(\mathrm{kg}\) ) and their height (in \(\mathrm{m}\) ). To calculate a person's BMI, divide their mass by the square of their height. (a) If a person's mass is \(m\), and their height is \(h\), write down the formula that would be used to calculate their BMI. (b) Jesse is \(1.75 \mathrm{~m}\) tall, and he weighs \(82 \mathrm{~kg}\). What is his BMI? (c) In a particular population, heights range from \(1.50 \mathrm{~m}\) to \(1.90 \mathrm{~m}\), and masses range from \(45 \mathrm{~kg}\) to \(160 \mathrm{~kg} .\) Calculate the maximum possible range of BMI's for this population.

Short Answer

Expert verified
Jesse's BMI is approximately 26.8. The BMI range for the population is from 12.5 to 71.1.

Step by step solution

01

Formula for BMI

To calculate the Body Mass Index (BMI) of a person, the formula used is: \[ \text{BMI} = \frac{m}{h^2} \] where \( m \) is the mass in kilograms (kg) and \( h \) is the height in meters (m).
02

Calculate Jesse's BMI

Jesse's mass is \( 82 \) kg and his height is \( 1.75 \) m. Plug these values into the formula: \[ \text{BMI} = \frac{82}{(1.75)^2} \] Calculate \((1.75)^2\): \(1.75 \times 1.75 = 3.0625\). So, \[ \text{BMI} = \frac{82}{3.0625} \approx 26.8 \]
03

Determine maximum BMI for the population

The maximum BMI occurs when the mass is at its maximum and the height is at its minimum. Using the values 160 kg (mass) and 1.50 m (height), the BMI is: \[ \text{Max BMI} = \frac{160}{(1.50)^2} \] Calculate \((1.50)^2\): \(1.50 \times 1.50 = 2.25\). So, \[ \text{Max BMI} = \frac{160}{2.25} \approx 71.1 \]
04

Determine minimum BMI for the population

The minimum BMI occurs when the mass is at its minimum and the height is at its maximum. Using the values 45 kg (mass) and 1.90 m (height), the BMI is: \[ \text{Min BMI} = \frac{45}{(1.90)^2} \] Calculate \((1.90)^2\): \(1.90 \times 1.90 = 3.61\). So, \[ \text{Min BMI} = \frac{45}{3.61} \approx 12.5 \]

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Key Concepts

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

Mathematical Formula for BMI
Body Mass Index, commonly known as BMI, is a simple yet effective way to assess whether a person's weight falls within a healthy range based on their height. To determine BMI, the following mathematical formula is used:
\[ \text{BMI} = \frac{m}{h^2} \]
In this formula, \( m \) represents the mass of an individual measured in kilograms, and \( h \) symbolizes height in meters. This formula essentially divides the mass by the square of the height. This means, effectively, that the distribution of body mass is being normalized over the body's height, providing a single numerical value representative of body fat for most people.
  • Easy calculation: Requires just mass and height.
  • Global applicability: Uses metric units that are standard worldwide.
Step-by-Step Calculation
Walking through the calculation step-by-step can demystify how the BMI formula works.Let's consider Jesse's example, who weighs 82 kg and is 1.75 meters tall. Here's how you'd calculate his BMI:1. **Compute the height squared**: First, find the square of Jesse’s height: - \((1.75)^2 = 3.0625\) This step involves multiplying Jesse's height by itself.2. **Substitute the values in the formula**: Insert Jesse’s weight and the squared height into the BMI formula: - \[ \text{BMI} = \frac{82}{3.0625} \]3. **Perform the division**: Divide Jesse's mass by the square of his height to find his BMI: - \[ \text{BMI} \approx 26.8 \]This precise, step-by-step method ensures clarity on how each component of the formula contributes to the final outcome, making BMI calculation straightforward for anyone to perform.
Population Data Analysis Using BMI
BMI isn’t just useful for individual analysis; it plays a crucial role in understanding population health trends. When considering a group with variation in height and weight, analyzing BMI ranges helps gauge overall health markers within that group.To explore the range of possible BMIs within a given population, consider the extremes of body metrics:
  • **Max BMI scenario**: Achieved with the highest weight and shortest height. - For example, using a weight of 160 kg and a height of 1.50 m: - Calculate the square of the height: \((1.50)^2 = 2.25\). - Substitute into the formula for maximum BMI: \[ \text{Max BMI} = \frac{160}{2.25} \approx 71.1 \]
  • **Min BMI scenario**: Achieved with the lowest weight and tallest height. - For example, using a weight of 45 kg and a height of 1.90 m: - Calculate the square of the height: \((1.90)^2 = 3.61\). - Substitute into the formula for minimum BMI: \[ \text{Min BMI} = \frac{45}{3.61} \approx 12.5 \]
These calculations can highlight the diversity in body composition across a population, providing insights into potential health risks or trends.

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Most popular questions from this chapter

Find the indicated partial derivatives. \(f(x, y)=\frac{x y}{x^{2}+2} ; f_{x}(-1,2)\)

Morphogenesis Most embryos start out as lumps of cells. Cells in these lumps are initially undifferentiated-that is, they start out all in the same state. Over time cells then commit to different functions, e.g., to becoming legs, eyes, and so on. To do this chemicals called morphogens are distributed unequally through the embryo, allowing each cell to tell where in the embryo it is located. How are unequal distributions of morphogens achieved? One model for how morphogens can be distributed through the embryo is that morphogens are continuously produced at one end (also called pole) of the embryo. From there they diffuse through the embryo. As the morphogens diffuse, they are constantly broken down by the cells in the embryo. First let's ignore the process of morphogen degradation, and focus only on diffusion. We will assume that the pole at which the morphogen is produced is located at \(x=0 ;\) and for simplicity's sake the cell occupies the interval \(x \geq 0\). Then our partial differential equation model for the distribution of morphogen becomes: $$ \frac{\partial c}{\partial t}=D \frac{\partial^{2} c}{\partial x^{2}} \quad \text { for } \quad x>0 $$ with $$ -D \frac{\partial c}{\partial x}(0, t)=Q \quad \text { and } \quad c(x, t) \rightarrow 0 \text { as } x \rightarrow \infty $$ where \(Q\) is the rate of morphogen production. (a) Let's try to find a steady state distribution of morphogen. That is, we will assume that over time the morphogen concentration reaches some state that does not change with time, i.e., the concentration is given by a function \(C(x) .\) Then \(C(x)\) will satisfy the partial differential equation if and only if: $$ \begin{aligned} 0 &=D \frac{d^{2} C}{d x^{2}} \quad \text { for } \quad x>0 \\ -D C^{\prime}(0) &=Q \quad \text { and } \quad C(x) \rightarrow 0 \text { as } x \rightarrow \infty \end{aligned} $$ Show that there is no function \(C(x)\) that satisfies this differential equation. [Hint: Start by integrating once \((10.48)\) to find \(d C / d x\) and then again to find \(\mathcal{C}(x)\), then try to impose the constraints at \(x=0\), and as \(x \rightarrow \infty\) on your solution.] (b) Now let's incorporate morphogen degradation into our model. We will assume that the breakdown of morphogen has first order kinetics (see Section \(5.9\) for a discussion of the different kinds of kinetics that chemical reactions may have). This means that in one unit of time a fraction \(r\) of the morphogen contained in each region of the embryo is degraded. Then our partial differential equation must be altered to: $$ \frac{\partial c}{\partial t}=D \frac{\partial^{2} c}{\partial x^{2}}-r c \quad \text { for } \quad x>0 $$ with $$ -D \frac{\partial c}{\partial x}(0, t)=Q \quad \text { and } \quad c(x, t) \rightarrow 0 \text { as } x \rightarrow \infty $$ Show that this partial differential equation does have a steady state solution of the form: $$ C(x)=Q \sqrt{\frac{1}{D r}} \exp \left(-\sqrt{\frac{r}{D}} x\right) $$ That is, check that this function \(C(x)\) satisfies both the steady state form of \((10.49)\) as well as the constraints at \(x=0\) and as \(x \rightarrow \infty\).

Find the range of each function \(f(x, y)\), when defined on the specified domain \(D\). \(f(x, y)=\ln (y-x) ; D=\\{(x, y): 0 \leq x \leq 1,0 \leq y \leq 1, y>x\\}\)

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