# Difference between revisions of "Exercise: Moving your finger through a flame without getting burned"

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− | Using the MATLAB | + | Using the MATLAB ode45 function (or something similar), build a model |

for the system and solve the following: | for the system and solve the following: | ||

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− | Plot the | + | Plot the ''steady state'' amplitude of the finger temperature as a |

function of the <math>\omega</math> for <math>\omega</math> ranging from 1 to 100 rad/sec. You | function of the <math>\omega</math> for <math>\omega</math> ranging from 1 to 100 rad/sec. You | ||

should get something similar to the frequency response plot shown in | should get something similar to the frequency response plot shown in | ||

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</p></li> | </p></li> | ||

− | <li><p> Double the | + | <li><p> Double the "gain" of the temperature control system by increasing |

<math>\alpha_b</math> by a factor of 2. Replot the frequency response from | <math>\alpha_b</math> by a factor of 2. Replot the frequency response from | ||

part~b and describe in words how it differs from the | part~b and describe in words how it differs from the |

## Revision as of 04:23, 29 September 2006

(Contributed by Demetri Spanos, 3 Oct 04)

In this problem we will look at how to play with fire without getting burned. The system we want to consider is a finger being moved back and forth across a flame, as shown below:

The description of the system is as follows:

The temperature of a finger is regulated by an internal feedback mechanism. To first order, we will say that heat is convected away by blood flow, at a rate

where is the temperature of the fingertip, is the temperature of the blood, and is the convection coefficient (the signifies the heat flux).

A flame gives off heat into the ambient air, and we assume steady-state temperature field around the flame. The ambient air far from the flame is at degrees Celsius.

The flame is fixed at , and fingertip begins at a position , where the ambient air is precisely at the same temperature as the blood.

Suppose that the temperature of the air varies exponentially with distance from the flame, so

where is the flame temperature.

Heat convects into the finger from the ambient air at a rate

The dynamics of the fingertip temperature is given by

where is the fingertip thermal capacity.

The fingertip is rapidly passed into and out of the flame, according to

Using the MATLAB ode45 function (or something similar), build a model for the system and solve the following:

Assume that the finger moves sinusoidally in and out of the flame at frequency rad/sec. Plot the temperature of the finger as a function of time and identify the transient and steady state response.

Plot the

*steady state*amplitude of the finger temperature as a function of the for ranging from 1 to 100 rad/sec. You should get something similar to the frequency response plot shown in lecture on Monday. You should compute at least 5 points in your graph.Double the "gain" of the temperature control system by increasing by a factor of 2. Replot the frequency response from part~b and describe in words how it differs from the original gain (i.e., where is the response bigger, smaller or unchanged and what is the reason).

You should use the following parameter values in your simulations:

, degrees Celsius.